NTSB Factual Report

HISTORY OF FLIGHT

On December 24, 2017, at 0717 eastern standard time, a Cessna 340 airplane, N247AT, impacted terrain after departure from Bartow Municipal Airport (BOW), Bartow, Florida. The private pilot and four passengers were fatally injured, and the airplane was destroyed. The airplane was registered to Aviation Transportation LLC and operated by the pilot under the provisions of Title 14 Code of Federal Regulations Part 91 as a personal flight. Instrument meteorological conditions prevailed at the time of the accident and an instrument flight rules (IFR) flight plan was filed. The flight was originating at the time of the accident with a planned destination of Key West International Airport (EYW), Key West, Florida.

The pilot filed an IFR flight plan on a Garmin GPS device and received an IFR clearance from the Tampa air traffic control tower. The BOW air traffic control tower was closed at the time of the accident.

According to two fixed base operator (FBO) employees at BOW, the pilot requested that the airplane be towed from the hangar to the ramp. The pilot stated that he wanted a tow so that he did not have to taxi next to the other hangars because of reduced visibility and dense fog. About 0645, the five occupants boarded the airplane and the FBO employees towed it to the ramp.

The FBO employees stated that the pilot started the engines and that they watched as the airplane very slowly taxied toward the end of runway 9L. The fog limited their visibility to about 400 ft. They could no longer see the airplane in the dense fog, so they moved to an area on the ramp closer to the runway. The pilot contacted Tampa Approach at 0710 for his IFR clearance. The FBO employees heard an increase in engine noise consistent with an engine run-up, and about 0715, they heard the airplane take off but they could not see the airplane because of the dense fog. The engines "sounded strong and [were] operating at full power" during the takeoff. They heard two tire "chirps" on the runway, then the sound of the airplane was consistent with a climb. They then heard an explosion on the east side of the airport and drove toward the explosion to find the airplane on fire. One of the FBO employees recorded a video of the airplane taxiing on the ramp toward the runway and another video of the takeoff.

The video captured by the FBO employee was 46 seconds long. While recording the video, the employee was located near the middle of the ramp and about 1/2 mile from the end of runway 9L. The accident airplane is not visible due to the dense fog. The sound of the engines is audible. The video pans from right to left and appears to follow the sounds of the airplane during the takeoff roll. At 26 and 28 seconds, two distinct chirps are heard. The video ends while the engines are still audible.

A helicopter pilot based at BOW observed the airplane taxiing on the ramp toward the runway. He recorded a video of the airplane taxiing on the ramp in the dense fog. He heard the airplane take off about 12 minutes later. During the takeoff, he heard a 'pop' similar to an engine backfire and about 3 seconds later, heard the explosion near the end of runway 9L. He and a colleague drove to the accident site, where they found the airplane engulfed in flames and saw the FBO employees nearby. He estimated that the runway visual range at the time was 600 to 800 ft due to the fog.

PERSONNEL INFORMATION

The pilot's logbooks were not located, and the pilot's instrument currency or proficiency could not be determined.

The mechanic who maintained the airplane stated that the pilot always flew with his feet flat on the floor and not on the rudder pedals. He also stated that the pilot never flew dangerously or recklessly. He added that the pilot's personal logbooks were always kept on the back shelf in the airplane.

The pilot's personal assistant stated that he always flew the airplane a couple of days before a flight with passengers. She stated that everyone she talked to described him as a good pilot and diligent with his pilot duties.

An acquaintance of the pilot, who also was the pilot's flight instructor in 2002, recounted flying the accident airplane with the pilot. He stated that the pilot mentioned an in-flight engine failure he experienced in the accident airplane. The pilot told him that he continued to his destination rather than making a precautionary single-engine landing because the logistics of diverting were too difficult. The acquaintance also stated that he and the pilot were supposed to fly the accident airplane together in early 2017. On the morning of the planned flight, he checked the weather conditions, which were about 1/4 mile visibility and 100 ft ceilings with dense fog. He told the pilot that they could not complete the flight because of the weather, and the pilot responded that, legally, they were allowed to fly under Part 91. The acquaintance had not talked to the accident pilot since that canceled flight.

A local airplane mechanic, who was a business acquaintance of the pilot, stated that he flew with the pilot one time and then refused to fly with him again. The acquaintance stated that he was not a safe pilot and took unnecessary risks.

AIRCRAFT INFORMATION

The mechanic who maintained the airplane stated that, 2 days before the accident, at the request of the pilot, he moved the co-pilot seat aft and adjusted the rear seats forward. He also stated that the accident airplane had a known autopilot issue; if the autopilot was engaged on the ground, it would command the elevator trim full nose-down. He understood this issue was a result of the autopilot's gyros not being level on the ground, which caused the autopilot to sense and attempt to compensate for a high pitch attitude. He stated that the accident pilot was aware of this autopilot issue.

The airplane logbooks did not reveal any past maintenance discrepancies or write-ups related to the autopilot or elevator trim.

One of the aforementioned BOW FBO employees reported that, on December 22, 2017, he received a fuel order from the pilot. He filled the airplane's tip tanks and auxiliary tanks with 100LL fuel; the nacelle tanks were already full. Later that day, he removed the airplane from the hangar; the pilot flew the airplane for about 30 minutes, then the employee towed the airplane back to the hangar.

A review of the left and right engine maintenance logbooks revealed entries for annual inspections that included an oil change and oil filter inspection and replacement on January 2, 2017, at 1,582.9 hours tachometer time. The previous two entries, dated December 20, 2015, and November 17, 2014, at 1,558.4 hours and 1,543 hours, respectively, noted an annual inspection was completed with oil and oil filter changes.

The oil filter found on the left engine at the accident site was marked with 1,543 hours tachometer time and dated January 6, 2014. When questioned about the discrepancy, the mechanic stated that the oil was actually not changed on either engine during the two previous inspections as noted in the logbooks and that the entries were not accurate. The mechanic stated that he planned to change the oil and replace the filters during the next annual inspection, which was due in January 2018.

The logbooks also revealed that the most recent IFR certification for the transponder and pitot static system was completed on June 20, 2014. To fly in IFR conditions the system must be inspected and certified every 24 calendar months.

METEOROLOGICAL INFORMATION

The automated weather observation station at BOW reported consistent weather conditions from 0635 to 0715, which included visibility less than 1/4 mile, fog, an overcast cloud layer at 300 ft, temperature 56°F, and an altimeter setting of 30.18 inches of mercury.

An area forecast discussion was issued for the region by the National Weather Service (NWS) that identified widespread shallow fog. An NWS dense fog advisory was in effect for Polk County, Florida. A center weather advisory was in effect for the accident area and advised of ceilings below 500 ft agl and visibilities below 1 mile in fog and mist. An AIRMET for IFR conditions was in effect for the accident area.

There was no evidence that the pilot obtained a preflight weather briefing from a recorded source.

WRECKAGE AND IMPACT INFORMATION

The accident site was located on airport property about 190 yards east-northeast of the departure end of runway 9L and 10 ft south of taxiway delta (figure 1).

The debris path was about 230 ft long and oriented northeast. The beginning of the debris path was defined by several ground impact craters in a line perpendicular to the debris path and the main wreckage. The middle impact crater contained pieces of the airplane's nose cowling and baggage door. Immediately to the right was the left engine's propeller. To the left of the middle crater was the right engine's propeller. A portion of the left wing tip fuel tank was found on the far right side of the initial impact area, and a portion of the right wing tip fuel tank was found on the far left side of the initial impact area. The main wreckage came to rest upright and oriented southeast about 30 ft from the initial impact craters. The fuselage was mostly consumed by fire and the empennage remained mostly intact with significant thermal damage. Both engines separated from the airplane and came to rest near the main wreckage. Airplane debris was found on the taxiway northeast of the main wreckage. The nose landing gear was separated from the airplane and found about 200 ft northeast of the main wreckage.

The flight controls exhibited impact and thermal damage but did not reveal any preimpact anomalies. The wing flap position could not be determined due to the extensive damage. The elevator trim tab was found beyond its full up limit. The elevator trim cable exhibited tension overload separations near the actuator and the other side of the cable was intact in the aft fuselage area. The elevator trim actuator was found at 2 ¼ inches, which was beyond the full length of travel (1.9 inches). The round hole in the trim tab surrounding the actuator rod was damaged and pushed aft by the rod end and bearing. The damage on the rod end matched the damage to the hole. The trim cable and chain on the top side of the actuator sprocket was pulled during the examination to test its functionality. When the cable was pulled, the actuator retracted and the trim tab lowered from its full-up position.

The landing gear actuator and the left and right main landing gear were all retracted.

Two attitude indicator gyros and one directional gyro were disassembled and examined. All three gyros exhibited rotational scoring inside the housings and along the circumference of the gyros. An electric turn-and-bank indicator gyro was disassembled and examined; it also exhibited rotational scoring.

The two vacuum pumps were separated from the engines and sustained significant impact damage. The right engine vacuum pump drive remained attached to the right engine and was melted by the postimpact fire. The left engine vacuum pump was separated from the engine, and the pump body and drive were intact. A portion of the vacuum manifold, which consisted of one of the end caps but no flapper valves, was found in the wreckage.

The left engine was separated from the airframe and was identified based on the data plate and maintenance records. The crankshaft was completely fractured at the nose oil seal and the propeller flange remained attached to the propeller hub. The crankshaft fracture surface displayed tearing, shear lips, and discoloration consistent with an overstress separation on impact. The top sparkplugs displayed a normal worn appearance with no signs of lead or carbon fouling. The bottom sparkplugs were examined via a lighted borescope with no anomalies noted. The return line from the fuel pressure regulator to the fuel pump remained in place and, when removed, residual fuel poured from the pressure regulator. The pump was disassembled, and the pump vanes were intact with no anomalies noted with the internal components.

The fuel manifold valve remained secured to the top of the engine and the fuel lines remained attached to the housing. The fuel lines remained secured to their nozzles and the upper deck reference line remained secured to the nozzles. The nozzles were free of obstructions. The fuel manifold screen was clear of contaminants and residual fuel was observed in the housing. The No. 2 intake inner valve spring was fractured. Residual oil was observed in each rocker cover. The cylinders were inspected and documented utilizing a lighted borescope. The No. 3 exhaust valve displayed two areas of green discoloration; otherwise, the pistons, valves, and valve seats were unremarkable. Manual rotation of the crankshaft was not possible due to impingements on the crankshaft and camshaft at the front of the crankcase and the oil sump, respectively. Sand and dirt from the accident site were embedded in the right exhaust slip joint area. The exhaust riser system on the aft end of the engine was crushed forward.

The left propeller hub remained intact and the piston was compressed aft. All three blades remained attached to the hub, but they were free to rotate in the hub, indicative of pitch change link fractures. The blades were labeled 1, 2, and 3 according to their hub location and for identification purposes only. Blade 1 was missing its counterweight, was bent aft slightly, and exhibited overstress signatures. The leading edge exhibited some light gouging and the cambered side exhibited chordwise scrapes and paint erosion. Blade 2 exhibited a small twist toward low pitch, paint erosion on the cambered side and leading edge gouges. The counterweight remained attached to the blade shank. Blade 3 was missing its counterweight, showed signs of overstress, and exhibited light chordwise paint erosion aft of the deice boot but was otherwise unremarkable.

The right engine was separated from the airframe and was identified based on the data plate and the maintenance records. The crankshaft was fractured at the nose oil seal and the propeller flange remained attached to the propeller hub. The crankshaft fracture surface displayed tearing, shear lips, and discoloration consistent with an overstress separation on impact. The engine sustained thermal damage.

The left magneto was separated from the engine and the ignition leads were separated from the harness cap. The right magneto remained in place and did not rotate with manual manipulation of the housing. The ignition harness remained secured to the right magneto and each terminal remained secured to their respective sparkplugs. The left magneto harness cap was removed and replaced with the right ignition harness cap from the left engine. Rotation of the drive shaft resulted in a spark from each lead in firing order during the audible snap of the impulse coupling. The right magneto was removed and the thermally damaged leads were cut near the harness cap. The magneto produced a spark from each of its leads in firing order when the drive shaft was manually rotated and the impulse coupling snapped.

The top sparkplugs were removed from the cylinders and all displayed a normal worn condition with no signs of lead or carbon fouling. The bottom sparkplugs were examined via a lighted borescope with no preimpact anomalies noted. The engine-driven fuel pump was separated from the engine; the mounting flange and drive coupling were displaced to one side and the metal was smeared in the same direction. The fuel manifold valve screen was free of obstructions and residual fuel was observed in the housing.

The cylinders remained attached to the crankcase with no external signs of operational distress. The cylinder rocker covers were removed and all of the valve springs remained intact. The cylinders were inspected and documented utilizing a lighted borescope. The pistons, valves, and valve seats were unremarkable. A tool was fitted to the backside of the crankshaft and partial crankshaft rotation was achieved, with continuity confirmed to the front of the engine and to the conn

NTSB Probable Cause

The pilot's loss of control due to spatial disorientation during takeoff in instrument meteorological conditions.