N40233

On July 5, 2023, about 1150Data block shows 1130

Pacific daylight time, a foreign-manufactured experimental motor glider, Avia Stroitel AC-5M, N40233, sustained substantial damage when it was involved in an accident near North Plains, Oregon. The private pilot sustained serious injuries. The motor glider was operated as a Title 14 Code of Federal Regulations Part 91 personal flight.

The pilot reported that after the recent purchase and condition inspection, he intended to perform a series of maneuvers as required by his insurance company. The motor glider was assembled at North Plains Gliderport (1OR4), North Plains, Oregon, followed by a series of towed high-speed taxis. The motor glider was towed for takeoff and released about 3,100 ft msl. To familiarize himself with the motor glider, he performed a climbing clearing turn to the right and trimmed the glider to hold 55 knots indicated airspeed (KIAS) on a southeast heading. Afterward, he performed a series of stalls and recovered from each uneventfully.

While flying straight and level about 2,500 ft msl, the pilot deployed and retracted the motor. While attempting a 30° - 45° right turn to the southeast, the pilot reported that the glider’s airspeed may have been too slow, and the glider immediately entered a clockwise, “very tight spiral dive.” The pilot neutralized the control stick, and applied left rudder pedal to recover. After several revolutions, he was able to stop the rotation and level the wings. He reported that, “the motor glider was moving at high speed as it was shaking.” The pilot reported that he applied gentle back pressure on the control stick, which was followed by an audible “bang” and he observed the right wing separate from the fuselage. He opened the canopy, deployed his parachute below 500 ft agl, and the landing was hard.

Examination of the motor glider logbook revealed that one month before the accident, a condition inspection was completed in accordance with the manufacturer’s inspection instructions and found to be in a condition for safe operation. The pilot reported that the weight of the motor glider at the time of the accident was 627 lbs. A review of the manufacturer’s flight manual revealed that the stall speed was about 42 KIAS, and the never-exceed speed was 120 KIAS. The pilot reported that the parachute was last packed in 2016. The parachute was required to be repacked every 6 months. He stated the previous owner only used the parachute as additional ballast.

Examination of the wreckage site revealed that the motor glider’s engine and propeller assembly remained attached to the fuselage and constituted the main wreckage. The left wing came to rest about 130 ft northeast of the main wreckage and the empennage came to rest about 398 ft northeast of the main wreckage. The right wing was the furthest point from the main wreckage and came to rest about 446 ft northeast. The left wing’s aileron sustained impact damage to the inboard and outboard attachment hinges, but remained connected to the aileron bellcrank. The right wing’s aileron was not damaged and remained connected to the wing at the respective hinge point and the bellcrank.

The motor glider’s wing root and composite spars were tapered to fit into corresponding carry-through boxes that connected in the aft fuselage. The left- and right-wing spar carry-throughs connected to the root rib of the opposite wing. The 70-pound wing panels were anchored by the carry-through with a single cam-actuated spar pin that cinched the wing assembly together. Aileron and divebrake controls mated automatically when the wings were installed.

Photographic evidence revealed that the right wing’s inboard spar was fracture separated. The left- and right-wing carry-through spar beams remained attached within the carry-through box and connected by the spar pin (see figure 1).

Figure 1. Accident site image of right-wing spar fracture separation.

Postaccident examination of the right-wing spar separation revealed that the fracture occurred in the spar at the outboard side of the reinforced area of the closeout rib, as seen in figures 2 and 3. The spar caps were constructed of a fiber-reinforced composite material separated by a web constructed of wood laminate.

Figure 2. Inboard end of the right wing with separated carry-through beam.

Figure 3. Inboard side of the right-wing spar fracture at the outboard end of the carry-through beam.

A materials lab examination revealed a cream-colored filler between the skin layers, and the fracture path varied between interfaces at either side of the filler. No evidence of preexisting or progressive fracture, such as arrest lines or rubbing damage from mating surfaces, was observed. (See figure 4.)

Figure 4. Sectioned right wing lower skin (upper image) and upper skin (lower image) after the upper skin was separated from the spar. The lower skin shows mating fracture surfaces at the inboard end of the leading-edge bond line.

Mating sides of the fracture through the right-wing spar upper cap are shown in figures 5 and 6. Fiber reinforcement layers were visible at the forward side of the upper spar cap, and the longitudinal reinforcement layers appeared to deviate from the spanwise direction outboard of the fracture surface. Dashed lines in figure 5 trace several of the reinforcement layers visible on the forward face of the upper cap showing observed variations in fiber alignment.

Figure 5. Mating sides of the right-wing spar upper cap fracture after the outboard side was separated from the upper skin. Dashed lines indicate the orientation of reinforcement layers visible on the surface.

As viewed on the outboard side (figure 6), the fracture surface mostly had a rough fibrous appearance consistent with tensile overstress fracture. A small portion of the surface at the upper side of the fracture had a whiter flattened appearance consistent with compression failure. At the lower quarter of the fracture, the exposed longitudinal fibers were angled downward relative to the spanwise direction.

Figure 6. Inboard side (upper image) and outboard side (lower image) of the right-wing spar upper cap fracture.

Mating sides of the right-wing spar fracture through the lower cap are shown in figure 7. The fracture surfaces had a rough fibrous appearance consistent with tensile overstress fracture. A relatively large pocket of fractured resin was observed at the lower aft side of the fracture, and that portion of the fracture was the furthest outboard. A wrinkle was observed in the fibers at the lower surface forward of the resin pocket. Additionally, brackets in figure 7 indicate fibers in the upper half of the fracture that were angled significantly downward relative to the spanwise direction.

Figure 7. Inboard side (upper image) and oblique view of the outboard side (lower image) of the right-wing main spar lower cap fracture.