Crash of a McDonnell Douglas MD-11F in Shanghai: 3 killed

Date & Time: Nov 28, 2009 at 0814 LT
Type of aircraft:
Operator:
Registration:
Z-BAV
Flight Phase:
Flight Type:
Survivors:
Yes
Schedule:
Shanghai - Bishkek
MSN:
48408/457
YOM:
1990
Flight number:
SMJ324
Country:
Region:
Crew on board:
7
Crew fatalities:
Pax on board:
0
Pax fatalities:
Other fatalities:
Total fatalities:
3
Circumstances:
The three engine aircraft departed Shanghai-Pudong Airport on a cargo flight to Bishkek, carrying various goods and seven crew members. During the takeoff roll from runway 35L, the pilot-in-command initiated the rotation but the aircraft did not lift off properly with had a negative vario. It overran the runway and eventually crashed in an open field. Three crew were killed while four others were injured. The aircraft was totally destroyed.
Probable cause:
The crew did not properly operate the thrust levers so that the engines did not reach take off thrust. The aircraft had not reached Vr at the end of the runway and could not get airborne. According to the design criteria of the MD11 the crew needs to push at least two thrust levers to beyond 60 degrees, which will trigger autothrust to leave "CLAMP" mode and adjust the thrust to reach the target setting for takeoff, the servo motors would push the thrust levers forward in that case. During the accident departure the pilot in the left seat did not advance the thrust levers to more than 60 degrees, hence the server motors did not work although autothrust was engaged but remained in CLAMP mode and thus did not adjust the thrust to reach takeoff settings. The crew members perceived something was wrong. Audibly the engine sound was weak, visibibly the speed of the aircraft was low, tactically the pressure on the back of the seat was weaker than normal. Somebody within the crew, possibly on the observer seats, suggested the aircraft may be a bit heavy. The T/O THRUST page never appeared (it appears if autothrust is engaged and changes from CLAMP to Thrust Limit setting. Under normal circumstances with autothrust being engaged a click sound will occur as soon as the thrust levers reach the takeoff thrust position. A hand held on the thrust levers will feel the lever moving forward, however, the crew entirely lost situational awareness. None of the anomalies described in this paragraph prompted the crews members' attention. When the aircraft approached the end of the runway several options were available: reject takeoff and close the throttles, continue takeoff and push the throttle to the forward mechanical stop, continue takeoff and immediately rotate. The observer called "rotate", the captain rotated the aircraft. This shows the crew recognized the abnormal situation but did not identify the error (thrust levers not in takeoff position) in a hurry but reacted instinctively only. As the aircraft had not yet reached Vr, the aircraft could not get airborne when rotated. As verified in simulator verification the decision to rotate was the wrong decision. The simulator verification showed, that had the crew pushed the thrust levers into maximum thrust when they recognized the abnormal situation, they would have safely taken the aircraft airborne 670 meters before the end of the runway. The verification also proved, that had the crew rejected takeoff at that point, the aircraft would have stopped before the end of the runway. The crew did not follow standard operating procedures for managing thrust on takeoff. The crew operations manual stipulates that the left seat pilot advances the thrust levers to EPR 1.1 or 70% N1 (depending on engine type), informs the right seat pilot to connect autothrust. The pilot flying subsequently pushes the thrust levers forward and verifies they are moving forward on servos, the pilot monitoring verifies autothrust is working as expected and reaches takeoff thrust settings. In this case the left seat pilot not only did not continue to push the thrust levers forward, but also called out "thrust set" without reason as he did not verify the takeoff thrust setting had been achieved. It is not possible to subdivide the various violations of procedures and regulations. The crew had worked 16 hours during the previous sector. In addition, one crew member needed to travel for 11 hours from Europe to reach the point of departure of the previous sector (Nairobi Kenya), two crew members need to travel for 19 hours from America to the point of departure of the previous sector. These factors caused fatigue to all crew members. The co-pilot was 61 years of age, pathological examination showed he was suffering from hypertension and cardiovascular atherosclerosis. His physical strength and basic health may have affected the tolerance towards fatigue. All crew members underwent changes across multiple time zones in three days. Although being in the period of awakeness in their biological rhythm cycle, the cycle was already in a trough period causing increased fatigue. The captain had flown the Airbus A340 for 300 hours in the last 6 months, which has an entirely different autothrust handling, e.g. the thrust levers do not move with power changes in automatic thrust, which may have caused the captain to ignore the MD-11 thrust levers. The co-pilot in the right hand seat had been MD-11 captain for about 7 years but had not flown the MD-11 for a year. Both were operating their first flight for the occurrence company. The two pilots on the observer seats had both 0 flight hours in the last 6 months. The co-pilot (right hand seat) was pilot flying for the accident sector. The captain thus was responsible for the thrust management and thrust lever movement according to company manual. A surviving observer told the investigation in post accident interviews that the captain was filling out forms and failed to monitor the aircraft and first officer's actions during this critical phase of flight. There are significant design weaknesses in the MD-11 throttle, the self checks for errors as well as degree of automation is not high.
Source: Aviation Herald/Simon Hradecky

Crash of a McDonnell Douglas MD-11F in Tokyo: 2 killed

Date & Time: Mar 23, 2009 at 0649 LT
Type of aircraft:
Operator:
Registration:
N526FE
Flight Type:
Survivors:
No
Schedule:
Guangzhou - Tokyo
MSN:
48600/560
YOM:
1993
Flight number:
FDX080
Country:
Region:
Crew on board:
2
Crew fatalities:
Pax on board:
0
Pax fatalities:
Other fatalities:
Total fatalities:
2
Captain / Total flying hours:
8132
Captain / Total hours on type:
3648.00
Copilot / Total flying hours:
5248
Copilot / Total hours on type:
879
Aircraft flight hours:
40767
Aircraft flight cycles:
7131
Circumstances:
Aircraft bounced repeatedly during landing on Runway 34L at Narita International Airport. During the course of bouncing, its left wing was broken and separated from the fuselage attaching point and the airplane caught fire. The airplane rolled over to the left being engulfed in flames, swerved off the runway to the left and came to rest inverted in a grass area. The Pilot in Command (PIC) and the First Officer (FO) were on board the airplane, and both of them suffered fatal injuries. The airplane was destroyed and the post-crash fire consumed most parts.
Probable cause:
In this accident, when the airplane landed on Runway 34L at Narita International Airport, it fell into porpoising. It is highly probable that the left wing fractured as the load transferred from the left MLG to the left wing structure on the third touchdown surpassed the design limit (ultimate load). It is highly probable that a fire broke out as the fuel spillage from the left wing caught fire, and the airplane swerved left off the runway rolling to the left and came to rest inverted on the grass area. The direct causes which the airplane fell into the porpoise phenomenon are as follows:
a. Large nose-down elevator input at the first touchdown resulted in a rapid nose down motion during the first bounce, followed by the second touchdown on the NLG with negative pitch attitude. Then the pitch angle rapidly increased by the ground reaction force, causing the larger second bounce, and
b. The PF‘s large elevator input in an attempt to control the airplane without thrust during the second bounce. In addition, the indirect causes are as follows:
a. Fluctuating airspeed, pitch attitude due to gusty wind resulted in an approach with a large sink rate,
b. Late flare with large nose-up elevator input resulted in the first bounce and
c. Large pitch attitude change during the bounce possibly made it difficult for the crewmembers to judge airplane pitch attitude and airplane height relative to the ground (MLG height above the runway).
d. The PM‘s advice, override and takeover were not conducted adequately. It is somewhat likely that, if the fuse pin in the MLG support structure had failed and the MLG had been separated in the overload condition in which the vertical load is the primary component, the damage to the fuel tanks would have been reduced to prevent the fire from developing rapidly. It is probable that the fuse pin did not fail because the failure mode was not assumed under an overload condition in which the vertical load is the primary component due to the interpretation of the requirement at the time of type certification for the MD-11 series airplanes.
Final Report: