Quoting the Materials Lab Report
The profile was transversely fractured separating the horizontal and vertical flanges. Fracture features such as shear lips and rough matte grey surfaces indicated tensile and shear overstress fracturing. There were no indications of fatigue or other progressive crack growth.The profile fracture exhibited a 2.5 to 3 inches long tensile overstress in the vertical flange. The tensile region was at the right edge of the vertical flange, near the profile’s fillet. The rest of the profile was fractured by shearing overstress in the horizontal flange. Figure 2 shows these fracture regions.
Figure 3 shows the large out-of-plane deformation of the horizontal flange of the profile, along with clear longitudinal elongations of the bolt holes, as shown in figure 1A. The vertical portion of the profile did not show any out-of-plane or within-plane deformation, but the two rightmost bolt holes exhibited elongation in the vertical direction.
Both plates showed similar overstress fracture characteristics. The fracture surfaces indicated a tensile overstress in the vertical direction, along the entire width of both plates. The fracture surfaces were more erratic (shifting planes) on the left side, as compared to the right side. There were no indications of fatigue crack growth.
Both plates exhibited similar plastic deformations at the left side of the fracture. As figure 4 shows, these deformations locally distorted the the left sides of the plates toward the left and aft, with respect to the aircraft.
The bolt holes in the right sides of the Y plates and in the short L profile, were elongated in the vertical direction, shown in figure 5. The portions connected to the fuselage also exhibited yielding around the right side holes at or near the fractures, as depicted in figure 6.
From the "Structures Study"
This airplane was climbing in a left hand circling pattern. It had reached about 4700 feet msl and started a slight descent and accelerated to about 100 to 110 mph groundspeed (derived from radar data)1. The airplane broke up in flight. The exact circumstances including airspeed and any maneuvering leading up to the breakup are unknown.
The breakup appears to have initiated in the forward V-tail attach structure. The lower attach angle (XNS-T09-04) separated in tension along the right side and further separated with the fracture running from the right to the left. The lower attach angle (XNS-T09-04) is fastened to and is an integral part of the forward spar structure of the stabilizers. It provides the angle for attachment points to the fuselage. As the lower attach angle was breaking, the structure that forms the rear attach Y-fitting also fractured and separated.
The kit designer estimated that the Waiex fleet has accumulated between 5,000 and 10,000 flight hours that include many aerobatic maneuvers. The kit designer is not aware of any other inflight structural breakup of this model airplane.
Photos of less-than-optimum construction are provided.
NOTE: The following loads evaluation is used to demonstrate how loads applied to a V- tail design may be greater than that of a conventional tail airplane. The evaluation is based on theoretical values that are not derived from the specific events of the accident at Washington, GA. In addition, the simple buildup does not allow for the rapidity of changes in AOA or yaw during the abrupt application of flight control inputs.
The V-tail design is often considered more aerodynamically efficient that a conventional tail design since the profile drag of the two surfaces is less than a three-surface configuration. However, each surface of a V-tail may have to provide both vertical and lateral components simultaneously. In some combinations, the structural maneuvering loads of the V-tail design may be significantly greater than the loads sustained on a conventional tail design.
A conventional empennage design isolates the vertical and horizontal components of flight loads to the respective vertical and horizontal surfaces of the empennage. A conventional horizontal stabilizer would be loaded by the increase in AOA and decrease in aft stick. Yaw and pedal inputs would not add to the loads on the horizontal stabilizer.
A V-tail design does not isolate the loading to a single axis. While vertical loading is equally distributed to both surfaces, similar to a conventional empennage, the lateral loading will be additive to one surface, and subtractive from the other2.
The following buildup presents a simplified example of loading to a V-tail structure while maneuvering. As can be seen, increasing the angle of attack (AOA) will increase the up load on the stabilizers. The up deflection of the ruddervators necessary to increase the AOA would decrease the up loading on the stabilizers. A yaw to the left would decrease the up loading on the left stabilizer and increase the loading on the right stabilizer. Pushing the right pedal would further lower the up loading on the left stabilizer and further increase the up loading on the right stabilizer. The step inputs incorporated into the calculations result in slightly higher than actual values since the AOA and yaw angles would be responding immediately to the start of the movement of the flight controls.
The build-up below follows a simple maneuver – pull the stick aft to increase the AOA, yaw left, followed by moving the stick forward and depressing the right pedal. In this case, the yaw and pedal input approximately double the load to the right stabilizer.
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