Aviation Accident Summaries

Aviation Accident Summary WPR14FA091

Pocatello, ID, USA

Aircraft #1

N903SR

CIRRUS DESIGN CORP SR22

Analysis

The pilot reported that, at 17,000 ft mean sea level, the engine suddenly started vibrating severely and partially lost power. He declared an emergency and an air traffic controller provided vectors for an instrument approach into a nearby airport. The pilot stated that the vibrations increased in severity and available engine power was decreasing. The pilot adjusted the mixture and throttle to no effect; he did not cycle the magnetos because he didn't want to risk losing engine power completely. After descending through the 2,000-ft broken cloud layer on the instrument approach, he determined that the airplane was not going to make it to the runway. At 1,000 ft above ground level, he deployed the Cirrus Airframe Parachute System, which brought the airplane down into an open field. He and his passenger rapidly exited the airplane before it was dragged away by the parachute in a 30-knot wind. Engine data indicated that, 2 hours 56 minutes into the flight, the engine rpm started to fluctuate. Two minutes later, the cylinder head temperature (CHT) of the No. 6 cylinder increased and peaked at 331 degrees F; 7 minutes later, it had decreased to 248 degrees F. At this point, the CHT for the No. 3 cylinder increased to 315 degrees F. About 3 hours 13 minutes into the flight, the engine exhaust gas temperatures (EGT) of cylinder Nos. 2, 4, 5, and 6 dropped off while the EGTs for cylinder Nos. 1 and 3 increased. Examination of the left and right magnetos revealed that the right magneto distributor drive gear had 10 teeth fractured off in the same gear sector, and the left magneto had 3 teeth broken in the same sector; all of the fracture surfaces on both gears exhibited crack arrest marks and river patterns consistent with progressive fracture. Based on the right magneto distributor gear damage, it is likely that the failure of the distributor drive gear teeth allowed the magneto distributor to stop rotating in proper firing order and allowed unsequenced repeated firing of the No. 6 cylinder and later the No. 3 cylinder, as reflected by the increase in CHT, which resulted in severe engine vibration and a partial loss of power. The unsequenced firing of the Nos. 6 and 3 cylinders also precipitated erratic power pulses through the engine that affected the left magneto distributor drive gear, which in turn initiated the left magneto distributor gear teeth failure. The pilot operating handbook lists the steps the pilot should take in the event of an engine partial power loss. Step seven of the engine partial power loss emergency procedures calls for the pilot to cycle through the left and right magnetos using the ignition switch. It is likely that, if the pilot had selected the left magneto after the initial indications of partial power loss and vibration, power could have been restored by isolating the right magneto and operating the engine entirely on the left magneto.

Factual Information

HISTORY OF FLIGHTOn January 9, 2014, at 1515 mountain standard time, a Cirrus Design Corp SR22, N903SR, experienced severe engine vibrations and a partial loss of engine power during cruise flight near Pocatello, Idaho. The pilot executed a forced landing utilizing the Cirrus Airframe Parachute System (CAPS). The private pilot and single passenger received minor injuries, and the airplane was substantially damaged. The airplane was registered to, and operated by, Nylund Imports Incorporated, under the provisions of 14 Code of Federal Regulations Part 91. Visual meteorological conditions prevailed for the flight, which operated on an instrument flight rules (IFR) flight plan. The flight originated from Centennial Airport, Denver, Colorado, at 1153, and was destined for Sun Valley, Idaho. The pilot reported that while passing Pocatello at 17,000 feet mean sea level (msl), the engine suddenly started vibrating severely in conjunction with a partial loss of power. He declared an emergency and Salt Lake Center provided vectors to the final approach course for the Pocatello instrument landing system (ILS) RWY 21 approach. The pilot stated that the vibrations increased in severity and available engine power was decreasing. The pilot adjusted the mixture and throttle to no effect. He did not switch between the two magnetos because he didn't want to risk losing engine power completely. After descending through the 2,000-foot broken cloud layer on the ILS approach, engine instruments indicated that only 20% power was being produced, and he determined that the airplane was not going to make it to the runway. At 1,000 feet above ground level (agl) he shut down the engine and deployed the Cirrus Airframe Parachute System (CAPS), which brought the airplane down into an open field. He and his passenger rapidly egressed before the airplane was dragged away by the parachute in a 30-knot wind. PERSONNEL INFORMATIONThe pilot, age 58, held a private pilot certificate with ratings for airplane single-engine land, multi-engine land, and instrument airplane issued December 28, 2003, and a third-class medical certificate issued January 30, 2012, with the limitation that he must have glasses available for near vision. The pilot reported having 2,159 total flight hours, with 2,046 hours in the accident airplane make and model, and 42 hours with in the previous 90 days. AIRCRAFT INFORMATIONThe four-seat, low-wing, fixed-gear airplane, serial number 2465, was manufactured in 2007. It was powered by a Continental Motors IO-550-N46B, 310-hp engine that had been modified with Tornado Alley turbonormalizing system by Cirrus and equipped with Hartzell model PHC-J3YFIN, 3-bladed composite constant speed propeller. Review of the airplane maintenance records show that an annual inspection was performed on December 13, 2013, at a total airframe and engine time of 850.3 hours. On September 2, 2010, at 496.2 engine hours, both magnetos were overhauled, and reinstalled on the engine. Engine Failure Procedures The SR22 Pilot Operating Handbook, Section 3, Emergency Procedures, dictate the following for Engine Partial Power Loss. "The following procedure provides guidance to isolate and correct some of the conditions contributing to a rough running engine of a partial power loss: 1. Air Conditioner – OFF 2. Fuel Pump – BOOST Selecting BOOST on may clear the problem if vapor in the injection lines is the problem or if the engine-driven fuel pump has partially failed. The electric fuel pump will not provide sufficient fuel pressure to supply the engine if the engine-driven fuel pump completely fails. 3. Fuel Selector – SWITCH TANKS Selecting the opposite fuel tank may resolve the problem if fuel starvation or contamination in one tank was the problem. 4. Mixture - CHECK appropriate for flight conditions 5. Power Lever – SWEEP. Sweep the Power Lever through the range as required to obtain smooth operation and required power. 6. Alternate Induction Air – ON 7. Ignition Switch – BOTH, L, then R. Cycling the ignition switch momentarily from BOTH to L and then R may help identify the problem. An obvious power loss in single ignition operation indicates magneto or spark plug trouble. If engine does not smooth out in several minutes, try a richer mixture setting. Return ignition to BOTH positions unless extreme roughness dictates the use of a single magneto. 8. Land as soon as practical." AIRPORT INFORMATIONThe four-seat, low-wing, fixed-gear airplane, serial number 2465, was manufactured in 2007. It was powered by a Continental Motors IO-550-N46B, 310-hp engine that had been modified with Tornado Alley turbonormalizing system by Cirrus and equipped with Hartzell model PHC-J3YFIN, 3-bladed composite constant speed propeller. Review of the airplane maintenance records show that an annual inspection was performed on December 13, 2013, at a total airframe and engine time of 850.3 hours. On September 2, 2010, at 496.2 engine hours, both magnetos were overhauled, and reinstalled on the engine. Engine Failure Procedures The SR22 Pilot Operating Handbook, Section 3, Emergency Procedures, dictate the following for Engine Partial Power Loss. "The following procedure provides guidance to isolate and correct some of the conditions contributing to a rough running engine of a partial power loss: 1. Air Conditioner – OFF 2. Fuel Pump – BOOST Selecting BOOST on may clear the problem if vapor in the injection lines is the problem or if the engine-driven fuel pump has partially failed. The electric fuel pump will not provide sufficient fuel pressure to supply the engine if the engine-driven fuel pump completely fails. 3. Fuel Selector – SWITCH TANKS Selecting the opposite fuel tank may resolve the problem if fuel starvation or contamination in one tank was the problem. 4. Mixture - CHECK appropriate for flight conditions 5. Power Lever – SWEEP. Sweep the Power Lever through the range as required to obtain smooth operation and required power. 6. Alternate Induction Air – ON 7. Ignition Switch – BOTH, L, then R. Cycling the ignition switch momentarily from BOTH to L and then R may help identify the problem. An obvious power loss in single ignition operation indicates magneto or spark plug trouble. If engine does not smooth out in several minutes, try a richer mixture setting. Return ignition to BOTH positions unless extreme roughness dictates the use of a single magneto. 8. Land as soon as practical." TESTS AND RESEARCHPrimary Flight Display and Multi-Function Display Data The Primary Flight Display (PFD) unit includes a solid state Air Data and Attitude Heading Reference System (ADAHRS) and displays aircraft flight data including altitude, airspeed, attitude, vertical speed, and heading. The PFD unit has external pitot-static inputs for altitude, airspeed, and vertical speed information. Each PFD contains two flash memory devices mounted on a riser card. The flash memory stores information the PFD unit uses to generate the various PFD displays. Additionally, the PFD has a data logging function which is used by the manufacturer for maintenance and diagnostics. The Multi-Function Display (MFD) unit is able to display checklists, terrain/map information, approach chart information, and other aircraft/operational information depending on the specific configuration and options that are installed. One of the options available is a display of comprehensive engine monitoring and performance data. Based on the data downloaded from the PFD & MFD the following event timeline was established. Time(approx) Elapsed Time Event 11:44:24 0:00 Engine Start 11:53:06 0:08:42 Take Off 14:38:30 2:54:06 Pressure alt starts to decrease (descent starts) 14:41:18 2:56:54 RPM starts to decrease/fluctuate 14:42:00 2:57:36 Increase fuel flow - pilot manipulates the mixture, then manipulates the throttle indicated by RPM changes 14:42:24 2:58:00 CHT* in No. 6 Cyl starts to trend upward 14:44:12 2:59:42 CHT in No. 6 Cyl Peaks 331° F 14:47:00 3:02:36 CHT No. 6 decreases to ~280°F 14:51:00 3:06:36 CHT No. 6 starts to trend upward ~248°F 14:52:18 3:07:54 CHT No. 3 starts to trend upward ~250°F 14:56:30 3:12:06 CHT No. 3 increases above the average peaking at~315°F 14:58:00 3:13:36 EGT** 2,4,5,6, drop off. EGT 1 & 3 increase. * CHT- cylinder head temperature **EGT - exhaust gas temperature The full data download and NTSB Vehicle Recorders Laboratory report are located in the official docket of this investigation. Engine Examination On April 15, 2014, the engine was examined at Continental Motors, Inc, under the supervision of the NTSB investigator-in-charge (IIC) with technical representatives from Continental Motors, Cirrus Aircraft, and Tornado Alley. The engine was removed from the shipping crate and placed on an engine stand for examination. The turbochargers and associated hardware had been removed and placed in the shipping container for shipping. The engine was visually examined and the crankshaft was rotated to verify engine drive train continuity. During the crankshaft rotation both magneto drives were observed through the pressurization port on the magneto housing. Both distributor gears were not moving in either magneto during the crankshaft rotation. The engine driven magneto metal drive gear interfaces with the light weight nylon composite distributor gear during operation. It was noted that the No. 3 ignition leads were producing a spark after the No. 1 ignition leads, indicating an improper firing order. The magnetos were removed for further examination. Examination of the magneto distributor gears revealed that the nylon composite gear teeth, 10 teeth on the right magneto and 3 teeth on the left magneto, had broken off. The fractured distributor gear teeth were clocked on an exemplary distributor gear in an exemplary magneto. The magneto drive shaft was rotated in a clockwise direction until the area of the separated teeth aligned with the drive gear. Doing so revealed that the separated gear teeth on the right magneto would have correlated to an area that placed the distributor gear electrode between the #6 and #3 cylinders' distributor block electrodes. Doing so on the left magneto revealed that the separated gear teeth would have correlated to an area that placed the distributor gear electrode between the #1 and #6 cylinders' distributor block electrodes. New magnetos were placed on the engine and the turbocharger system reinstalled. The engine was then successfully test run to full power in a test cell, and no anomalies were noted. Magneto Distributor Gear Examination The left and right nylon magneto distributor drive gears and separated teeth were sent to the NTSB Materials Laboratory for further investigation. The magneto distributor had undergone 860.4 hours at the time of the accident. The last magneto inspection was performed at 496.2 hours on September 2, 2009. The required inspection interval is 500 hours. Three of the teeth on the left gear had fractured off. The fracture surfaces of all three broken gear teeth exhibited crack arrest marks and radial river patterns that were consistent with progressive failure. All three fracture surfaces exhibited features consistent with crack propagation in the same direction. Examination of the right gear showed 10 of the teeth had fractured. Similar to the left gear, the fracture surfaces of the right gear exhibited features consistent with progressive cracking. The teeth fractures generally progressed circumferentially away from a central point on the gear, as opposed to all in one direction. In addition, there was a 0.5-inch radial crack present on one of the tooth fracture surfaces. Similar to the left gear, all of the fracture surfaces on the right gear exhibited crack arrest marks and river patterns consistent with a progressive fracture. The fracture surfaces of the right gear were sectioned and gold sputter-coated to facilitate examination in a scanning electron microscope (SEM). The initiation region of the fracture was generally flat and smoother than the rest of the fracture surface. There were no material defects noted at the crack initiation site that might have led to premature failure. The full NTSB Materials Laboratory report is available in the official docket of this investigation.

Probable Cause and Findings

The distributor gear teeth failure of the right magneto that resulted in severe engine vibration and partial loss of engine power, which progressively led to the failure of the left magneto distributor drive gear teeth. Contributing to the airplane’s continued operation with the partial loss of engine power was the pilot’s failure to execute all steps in the engine partial power loss procedure.

 

Source: NTSB Aviation Accident Database

Get all the details on your iPhone or iPad with:

Aviation Accidents App

In-Depth Access to Aviation Accident Reports