N534P

HISTORY OF FLIGHT

On November 24, 2011, about 1223 universal coordinated time, a Piper PA-46-350P, N534P, operated by Boeck & Boeck Incorporated, was substantially damaged during a ditching in the Caribbean Sea following a loss of engine power during cruise flight approximately 119 nautical miles west of Fort de France, Martinique. The certificated commercial pilot and his pilot rated passenger received serious injuries. Visual meteorological conditions (VMC) prevailed for the flight that departed Rafael Hernandez Airport (TJBQ), Aguadilla, Puerto Rico, destined for Maurice Bishop International Airport (TGPY), St. George's, Grenada. An instrument flight rules (IFR) flight plan was filed for the ferry flight conducted under 14 Code of Federal Regulations (CFR) Part 91.

According to the pilot, he had recently sold the airplane and was ferrying the airplane on a multiple leg ferry flight to the new owner in Brazil.

During the leg between TJBQ to TGPY they had taken off and climbed to 27,000 feet (Flight Level 270). During cruise over open water at FL270 about 40 minutes flight time from TGPY, almost simultaneously; the airspeed began to decrease, the engine torque indication went from 937 foot-pounds (ft-lbs) of torque to 0 ft-lbs of torque, the engine began to vibrate, and smoke began emanating from the engine. The pilot then reduced power to idle, moved the propeller control lever to the feather position, moved the fuel condition lever to the off position, and the firewall fuel shutoff lever to the off position. He then alerted Piarco air route traffic control center (ARTCC), Port of Spain, Trinidad, and advised them of his emergency and turned towards the island of Martinique which was the closest island. Piarco ARTCC then asked him of his intentions, and handed him off to Martinique air traffic control (ATC). The pilot then activated the onboard 406 emergency locator transmitter and proceeded in the direction of Martinique at best glide speed. The pilot tried to restart the engine but, it began to immediately smoke and vibrate and he terminated the start sequence. He then had his pilot rated passenger move to the back of the airplane and both he and the passenger donned their life vests. The passenger then retrieved the life raft, first aid kit, and a portable ELT, and readied them for deployment. The pilot then instructed him to open the top half of the main cabin door prior to impact.

Just prior to touchdown, the pilot observed that the water was choppy with waves approximately 6 feet in height. The airplane then impacted the water tail first at stall speed and bounced approximately three times before coming to rest on the surface of the water. During the impact, the pilot hit his head. After unstrapping he then turned around to exit the cockpit and observed that the raft had deployed in the cabin and his passenger was trapped. He then moved to the back of the cabin and he and the passenger pushed the raft out the main cabin door. After exiting, he tried to shut the main cabin door but his passenger was having difficulty swimming. The pilot then abandoned his attempt to close the door and assisted the passenger. They both boarded the life raft and the airplane sank approximately 15 minutes later.

According to French Authorities, after the pilot advised Piarco ARTCC at 1206 of the engine failure, Piarco ARTCC contacted the French Navy which has a dual role as coast guard and defense for the French overseas departments and territories, and advised Martinique ATC of the emergency. A commuter air carrier aircraft, a French navy airplane, and a French navy helicopter were then vectored in the direction of the airplane. At approximately 1223 the airplane was considered to be down and at 1308 the first airplane arrived overhead. The helicopter arrived at 1355 and both occupants were sling lifted onboard and flown to Fort de France, Martinique.

PERSONNEL INFORMATION

According to Federal Aviation Administration (FAA) records, the pilot held a commercial pilot certificate with ratings for airplane single-engine land, airplane single-engine sea, airplane multi-engine land, and instrument airplane. He also held a flight instructor certificate with ratings for airplane single-engine and instrument airplane. His most recent application for a FAA third-class medical certificate was dated September 1, 2011. The pilot reported that he had accrued 2,175 total hours of flight experience, of which 643 hours were in the accident airplane make and model.

AIRCRAFT INFORMATION

The accident aircraft was a six-seat, single-engine, low wing, pressurized airplane of conventional metal construction. It was originally manufactured by Piper Aircraft in 2007 as a PA-46-350P.

It was equipped with retractable landing gear and was converted to a JetProp DLX when it had its original engine replaced with a 750 shaft horsepower Pratt & Whitney Canada (PWC) PT6A-35, turbo propeller engine in June of 2011.

At the time of the conversion the airplane had accrued 200.7 total hours of operation. At the time of the accident the engine had accrued approximately 15 hours of operation.

It could operate at an indicated airspeed of 260 knots at 27,000 feet above mean sea level.

METEOROLOGICAL INFORMATION

The reported weather at TJBQ at 1050, included: winds 110 degrees at 4 knots, 10 miles visibility, sky clear, temperature 22 degrees C, dew point 20 degrees C, and an altimeter setting of 30.00 inches of mercury.

The reported weather at TFFF at 1200, included: winds 060 degrees at 4 knots, 4 miles visibility in light rain, scattered clouds at 1,000 feet, scattered clouds at 3,000 feet, broken clouds at 4,300 feet, temperature 24 degrees C, dew point 24 degrees C, and an altimeter setting of 29.94 inches of mercury.

TESTS AND RESEARCH

Fueling Information

According to the fixed base operator (FBO) who serviced the airplane at TJBQ prior to the flight the pilot had the fuel topped off prior to departure. 126 gallons of Jet A was added but the pilot did not request the addition of any fuel icing additive though he was planning to conduct the flight at 27,000 feet and the airplane was not equipped with fuel heaters.

Review of the FBO's fuel quality test records did not reveal any anomalies with the Jet A that was provided.

Maximum Ramp and Operating Weight

According to the JetProp DLX Pilot's Operating Handbook and FAA Approved Airplane Flight Manual (POH/AFM) the maximum ramp weight was 4,358 pounds and the maximum takeoff weight was 4,340 pounds. According to the pilot however, he departed TJBQ at 4,650 pounds.

Climb and Cruise Information

Review of radar information revealed that the airplane after takeoff climbed to 27,000 feet in approximately 27 minutes, which averaged out to an approximate 1,000 foot per minute rate of climb. Review of the POH/AFM, however, revealed that no power setting or performance information was available for the declared takeoff weight of 4,650 pounds.

Review of the POH/AFM revealed that the airplane would have burned approximately 16 gallons of fuel during the climb resulting in an approximate weight at top of climb of approximately 4,543 pounds. No performance or power setting information was available for this weight either.

According to the pilot, during cruise prior to the loss of engine power, torque was indicating "around 937" ft-lbs of torque. According to the pilot rated passenger however, prior to the failure, the Torque Gauge was indicating approximately "980" ft-lbs. Review of the maximum cruise performance chart in the POH/AFM revealed that both of the stated torque settings exceeded the maximum torque setting listed on the chart.

Recommended PT6A Engine Power Management

Pratt & Whitney Canada Document 09-1331 (Know Your PT6A) states in part that, a mission profile is established for every PT6A engine application. This mission is used to analyze and establish engine component lives and durability factors such as low cycle fatigue, creep, oxidation, and vibration. Using this data and taking into consideration airframe influences such as bleed extraction, accessory loading and inlet efficiency, the power setting information is established and then published in the POH/AFM.

Power Rating Philosophy

This power rating philosophy is used to ensure the maximum likelihood that the PT6A engine will deliver the power specified in the POH/AFM throughout its life. To achieve this, all PT6A engine installations use torque as the primary power setting parameter. All other engine parameters are only monitored to verify they are within acceptable limits. The POH/AFM contains power setting information which must be used to determine the torque setting for all ratings which vary according to altitude, ambient temperature and aircraft weight. This is important because the PWC rating philosophy is based on the engine being operated per the POH/AFM to achieve optimum reliability and durability.

Some of these power ratings are:

• The take-off rating, which is the maximum power certified for takeoff and is time limited to five minutes.

• The maximum continuous rating, which is a certified power setting for in-flight emergency use only, typically for twin engine applications where one engine is inoperative.

• The maximum climb and maximum cruise ratings which are the maximum powers approved by PWC for climb and cruise operation.

Power Settings

All PT6A engine applications also use engine output torque as the primary power setting parameter. The POH/AFM contains power setting information which must be used to determine the correct torque settings to achieve take off and cruise in accordance with altitude, ambient temperature and aircraft weight.

The power lever should be set to the position which produces the required torque. Other engine parameters such as inter turbine temperature (ITT) and gas generator speed (Ng) are monitored only to verify that they are within acceptable limits. Operat...