The fatal July 6, 2016 in-flight break-up
of Bell 525 flight test vehicle 1 (FTV-1) was caused by "severe
vibration of the helicopter that led to the crew's inability to maintain
sufficient rotor rotation speed (Nr), leading to excessive main rotor blade flapping,
subsequent main rotor blade contact with the tail boom, and the resultant
in-flight breakup," according to the NTSB final report released on
January 16.
The NTSB wrote, "Contributing to the
severity and sustainment of the vibration, which was not predicted during
development, were (1) the collective biomechanical feedback and (2) the
attitude and heading reference system response, both of which occurred due to
the lack of protections in the flight control laws against the sustainment
and growth of adverse feedback loops when the 6-hertz airframe vibration
initiated. Contributing to the crew's inability to maintain sufficient Nr in
the severe-vibration environment were (1) the lack of an automated safeguard
in the modified one-engine-inoperative software used during flight testing to
exit at a critical Nr threshold and (2) the lack of distinct and unambiguous
cues for low Nr."
The vibration initiated at 92 percent Nr
excited the main rotor scissors mode, meaning the adjacent blades were moving
together and apart in a scissors motion. This resulted in a 6-Hz airframe
vibration that, the NTSB concluded, "was transmitted to the crew seats
and created a biomechanical feedback loop through the pilot-held collective
control. A second feedback system, driven by the attitude and heading
reference system (AHRS) inputs to the main rotor swashplate, also continued
to drive the scissors mode and its resultant 6-Hz airframe vibration."
The accident occurred during a simulated
OEI (one engine inoperative) test with forward center of gravity at 185
knots. The test used special software to reduce the power in both engines to
simulate OEI. At the time of the accident, FTV-1 was equipped with a
combination flight data recorder/cockpit voice recorder (CVFDR), but it was
not activated, nor was it required to be under FAA rules for flight
test/experimental operations.
Neither pilot made radio transmissions
during the accident sequence, which was monitored from close range by a chase
aircraft and by ground-based telemetry and test team members. They noticed
the increased vibration during the fatal test and radioed instructions to
"knock it off" during the accident sequence. The chase aircraft
also radioed cautions to the FTV-1 pilots during the test about excessive
blade flapping.
The NTSB noted, "After the crew
engaged OEI special training mode, rotor rotation speed (Nr) decayed from 100
percent to about 91 percent, and the crew began lowering the collective to
stop Nr decay and increase Nr to 103 percent (the target Nr for recovery).
About 5.5 seconds into the test, the crew stopped lowering the collective,
and Nr only recovered to about 92 percent. About 6 to 7 seconds into the
test, the helicopter began vibrating at a frequency of 6 Hertz.
"The vibration was evident in both
rotor systems, the airframe, the pilot seats, and the control inputs; the
vertical vibration amplitude at the pilot seat peaked at about 3 G. Nr
remained between about 90 percent and 92 percent until about 12 to 13 seconds
into the test, then began fluctuating consistent with collective control
inputs; subsequent collective control input increases led to further decay in
Nr.
"Nr decayed to about 80 percent as
the collective was raised, and the main rotor blades began to flap out of
plane. About 21 seconds into the test, the main rotor blades flapped low
enough to impact the tail boom, severing it and causing the in-flight breakup
of the helicopter," according to the NTSB report.
RETURN TO FLIGHT TEST
Since the crash, Bell has made numerous
changes to the 525 and its test program. These include:
Bell resumed flight testing of the 525 on July 7, 2017. In a
prepared statement, Bell said, "An in-depth analysis of the flight data
resulted in a thorough understanding of the corrective actions necessary, and
appropriate changes to the aircraft have been implemented. A carefully planned
approach is under way to complete the remaining certification flight testing.
We remain committed to the 525 program-the continued work of the program team
will result in a reliable, innovative helicopter with advanced rotorcraft
safety features when it comes to market."
Further, Bell said the changes/enhancements made to the 525
post-crash "are being carefully tested to ensure that our corrective
actions have fully addressed the unique problem encountered on July 6,
2016." It said the vibrations encountered on the fatal flight were
"the result of an unanticipated combination of very high airspeed with a
sustained low rotor rpm condition."
Due to the lack of a functioning CVR in the accident aircraft,
investigators could only theorize why it took the test pilots so long to
recover from the low Nr condition that soon became fatal. On previous OEI
tests at slower speeds the crew had lowered the collective to 50 percent to
recover, during the accident sequence it was lowered only to 58 percent.
Recovery times required increased with airspeed.
"Investigators explored possible reasons why the
crewmembers stopped their recovery from the initial Nr drop, including a
reaction to an abnormal condition on the helicopter, distraction from the
recovery task, or a conservative response due to the high airspeed. Telemetry
data does not indicate the existence of an abnormal condition when the
crewmembers stopped their recovery," the NTSB noted.
Based on interviews with Bell flight-test members, the NTSB
noted, "Helicopter manufacturer test pilots indicated that they
interpreted this trend as the tendency of the crew to be more judicious while
applying collective at successively higher airspeeds to avoid recovering too
fast and overspeeding the rotor or damaging the transmission. Thus, the crew
may have been more conservative during recovery at the helicopter's high
speed during the final test. The chief test pilot also stated that if Nr had
stabilized, the pilot would not have been in a rush and was possibly
initiating a slow recovery."
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