The Space Shuttle Orbiter wing comprises of 22 leading edge panels on each side of the wing. These panels are part of the thermal protection system that protects the Orbiter wings from extreme heating that take place on the reentry in to the earth atmosphere. On some panels that experience extreme heating, liberation of silicon carbon (SiC) coating was observed on the slip side regions of the panels. Global structural and local fracture mechanics analyses were performed on these panels as a part of the root cause investigation of this coating liberation anomaly. The wing-leading-edge reinforced carbon-carbon (RCC) panels, Panel 9, T-seal 10, and Panel 10, are shown in Figure 1 and the progression of the stress analysis models is presented in Figure 2. The global structural analyses showed minimal interaction between adjacent panels and the T-seal that bridges the gap between the panels. A bounding uniform temperature is applied to a representative panel and the resulting stress distribution is examined. For this loading condition, the interlaminar normal stresses showed negligible variation in the chord direction and increased values in the vicinity of the slip-side joggle shoulder. As such, a representative span wise slice on the panel can be taken and the cross section can be analyzed using plane strain analysis

Knight, Norman F., Jr.

Phillips, Dawn R.

Raju, Ivatury S.

Song, Kyongchan

Frattura ed Integrità Strutturale

The Space Shuttle wing-leading edge consists of panels that are made of reinforced carbon-carbon. Coating spallation was observed near the slip-side region of the panels that experience extreme heating. To understand this phenomenon, a root-cause investigation was conducted. As part of that investigation, fracture mechanics analyses of the slip-side joggle regions of the hot panels were conducted. This paper presents an overview of the fracture mechanics analyses

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Fracture Mechanics Analyses of the Slip-Side Joggle Regions of Wing-Leading-Edge Panels

The Space Shuttle wing-leading edge consists of panels that are made of reinforced carbon-carbon.  Coating spallation was observed near the slip-side region of the panels that experience extreme heating.  To understand this phenomenon, a root-cause investigation was conducted.  As part of that investigation, fracture mechanics analyses of the slip-side joggle regions of the hot panels were conducted.  This paper presents an overview of the fracture mechanics analyses

Kyongchan Song

Dawn R. Phillips

Norman F. Knight, Jr.

Ivatury S. Raju

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Fracture mechanics analyses of the slip-side joggle regions of  wing-leading-edge panels

Fracture Mechanics Analyses of the Slip-side Joggle Regions of 
Wing-Leading Edge Panels 
Ivatury S. Raju 
NASA Langley Research Center 
Hampton, VA, 
 
Norman F. Knight, Jr. 
General Dynamics Information Technology 
Chantilly, VA, 
 
Kyongchan Song 
ATK Space Division 
Hampton, VA, 
 
Dawn R. Phillips 
NASA Marshall Space Flight Center 
Huntsville, AL 
 
Extended abstract for the 9th Youth Symposium on Experimental Solid Mechanics (YSESM) 
July 7-10, 2010, Triste, Italy  
 
The Space Shuttle Orbiter wing comprises of 22 leading edge panels on each side of the 
wing.  These panels are part of the thermal protection system that protects the Orbiter wings 
from extreme heating that take place on the reentry in to the earth atmosphere.   On some panels 
that experience extreme heating, liberation of silicon carbon (SiC) coating was observed on the 
slip side regions of the panels.    Global structural and local fracture mechanics analyses were 
performed on these panels as a part of the root cause investigation of this coating liberation 
anomaly. The wing-leading-edge reinforced carbon-carbon (RCC) panels, Panel 9, T-seal 10, 
and Panel 10, are shown in Figure 1 and the progression of the stress analysis models is 
presented in Figure 2.   The global structural analyses showed minimal interaction between 
adjacent panels and the T-seal that bridges the gap between the panels.   A bounding uniform 
temperature is applied to a representative panel and the resulting stress distribution is examined.  
For this loading condition, the interlaminar normal stresses showed negligible variation in the 
chord direction and increased values in the vicinity of the slip-side joggle shoulder.   As such, a 
representative span–wise slice on the panel can be taken and the cross section can be analyzed 
using plane strain analysis.  
https://ntrs.nasa.gov/search.jsp?R=20100026832 2019-08-30T10:22:04+00:00Z
Extensive fracture mechanics studies for extreme thermal loading conditions were 
performed with subsurface defects.  Plane strain fracture mechanics models were developed 
using the Panel 10 slip-side joggle configuration with discrete layers of SiC coating and RCC 
substrate materials (see Figure 3).  The transverse craze cracks in the SiC coating layers were 
explicitly modeled including craze crack edge interaction (or surface friction) when the edges are 
in contact.  Two types of defects, subsurface defects at the interface between the SiC/RCC 
substrate (interface defects) and defects within the RCC substrate (substrate defects), were 
considered.  Various lengths of defects along the joggle and in the acreage were analyzed.  Both 
entry heating and on-orbit cold conditions were used in the analyses.  The objective of the 
fracture mechanics analyses is to determine the defect-driving force associated with different 
subsurface defects.  The total defect-driving force and its components are characterized by the 
strain energy release rates, G-values, computed using the virtual crack-closure technique 
(VCCT).  The total defect-driving force is compared to a critical value. If the defect-driving 
force is less than the critical value then the defect is stable. If, on the other hand, the defect-
driving force is greater than or equal to the critical value, then the defect will grow in an unstable 
manner and fast fracture is predicted to occur.  Representative fracture mechanics results for 
interface defects are presented in this paper. 
To study the effects of the interface defect location along the joggle, the interface defect is 
moved to the different craze crack locations shown in Figure 3 (i.e., from Location 0 (Baseline-I) 
to Location +1, then Location +2, etc.).  For lift-off and ascent bounding loading cases, the 
GT/GIc values obtained for the Baseline-I model are essentially zero.  These loading conditions 
are considered to be benign, and hence, no further analyses are performed for interface defects 
subjected to the lift-off and ascent loading conditions. 
The interface defect locations are analyzed for the bounding on-orbit cold thermal loading 
condition.  For this condition, the craze cracks open and no craze crack edge interaction occurs.  
The results are shown in Figure 4.  The deformed configurations for each defect location are 
shown at the top of the figure.  The GT/GIc values for the left and right defect tips are plotted at 
the bottom of the figure as a function of the horizontal distance from Location 0.  The GT/GIc 
values for both the left and right defect tips at every location are nearly constant, with the highest 
value at the left tip of the defect at Location 0, GT/GIc = 1.6.  The GT/GIc values for all of the 
defect tips are greater than unity.  Therefore, this condition requires further examination.  If GT is 
Mode I-dominated, then the defect is unstable.  However, the fracture response for the on-orbit 
cold condition is a Mode II-dominated response, and the ratio of GIIc/GIc is about four.  Hence, 
such an interface defect is predicted to be stable for the bounding on-orbit cold condition. 
The interface defect locations are analyzed for the bounding entry loading condition.  For this 
condition, the craze cracks close and craze crack edge interaction occurs.  The results are shown 
in Figure 5.  The deformed configurations for each defect location are shown at the top of the 
figure.  The GT/GIc values for the left and right defect tips are plotted at the bottom of the figure 
as a function of the horizontal distance from Location 0 for two values of the coefficient of 
friction : =0 for perfectly smooth surfaces and =0.4 smooth surfaces.  The GT/GIc values for 
the right tips are much higher than the GT/GIc values at the left tips, with the highest value at the 
right tip of the defect at Location 0, GT/GIc = 2.0 for =0 and GT/GIc = 0.81 for =0.4.  If GT is 
Mode I-dominated, then the defect is unstable when the craze crack edges are perfectly smooth.  
The GT/GIc values are less than unity when the craze crack edges are smooth (friction is 
included), and hence, these defects are stable. 
From the global three-dimensional analyses, it was concluded that the slip-side joggle 
region was the region of interest, that increased interlaminar stress levels developed in this 
region for entry conditions, and that a plane strain modeling approach of this region is applicable 
for bounding analyses.  From the fracture mechanics analyses of the interface defects, it was 
concluded that interface defects have the potential of becoming unstable and may lead to 
liberation of a coating ‘island’ during entry.  From the analyses of the substrate defects, substrate 
defects also appear to have the potential to become unstable depending on their location and 
length along the joggle.  This paper summarizes features of the global stress and fracture 
mechanics analyses and discusses some salient results. 
 
 
 
 
 
 
 
 
a) Global shell model      (b) Global 3D model 
Figure 1.  Integrated model of Panel 9, T-seal 10 and Panel 10. 
  
 
 
 
 
 
 
 
 
 
 
Figure 2.  Global structural and fracture mechanics models. 
 
Figure 3.  Slip-side joggle configuration with defect location index and Baseline-I interface 
defect at Location 0. 
 
 Figure 4. On-orbit deformed configurations and GT/GIc values for single interface defect at 
different craze crack locations. 
 
Figure 5. Entry deformed configurations and GT/GIc values for single interface defect at different 
craze crack locations. 
 


Fracture Mechanics Analyses of the Slip-Side Joggle Regions of Wing-Leading Edge Panels

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Fracture Mechanics Analyses of the Slip-Side Joggle Regions of Wing-Leading Edge Panels

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