NTSB CAROL · Event
Event ANC18LA051
Aircraft involved
Probable cause & findings
The total loss of engine power due to fuel starvation for reasons that could not be determined, which resulted in impact with and subsequent sliding across terrain.
Factual narrative
On June 29, 2018, about 1307 Alaska daylight time, a float-equipped Piper PA-18 airplane, N7675D, sustained substantial damage when it was involved in an accident at Lake Hood Seaplane Base (LHD), Anchorage, Alaska. The pilot sustained minor injuries and the passenger was uninjured. The airplane was operated as a Title 14 Code of Federal Regulations Part 91 personal flight. The pilot stated that he and the pilot-rated passenger fueled the airplane before the flight from his private fuel tank at his floatplane slip and that the preflight inspection and engine run-up were normal. The pilot was conducting a takeoff from the rear seat. During the initial climb from the north water lane, when the airplane was between about 100 and 200 ft above ground level (agl), the engine began to "sputter" and lose power. Realizing he would not be able to land on the water, the pilot turned the airplane to land on a nearby gravel runway and asked the passenger to check that the fuel selector valve was in the "on" position, and he responded that it was. He "pumped" the throttle to restore power to no avail. The airplane subsequently impacted the grassy area between the runway and a taxiway. The passenger statement corroborated the pilot’s statement, but he added that the airplane landed with a nose-high attitude and then banked right. The airplane then slid across a taxiway and another grassy area and sustained substantial damage to the fuselage and wings. The airplane came to rest on a heading of about 070°. Examination of the airplane revealed that it had sustained substantial damage to the fuselage and wings. At the accident site, a large amount of fuel was observed leaking from the left wing root. Examination of the pilot’s private fuel tank and system revealed that some debris was in the fuel nozzle, but no water or debris was found in a fuel sample taken from the nozzle. Postaccident examination of the engine and fuel system was conducted 2 months after the accident, during which time, the engine cowling was off, and the wreckage and engine were exposed to rain. The engine was attached to the airframe and intact, and the fuel and oil lines were secure. The fuel selector switch was found positioned to the “left fuel on” position. The propeller assembly remained connected to the engine crankshaft and could be rotated by hand. One propeller blade had a rearward curl and slight S bend at the outer 8 inches and exhibited leading edge impact damage and scrapes. The other blade was straight with extensive trailing edge impact damage and dirt and grass dried onto the cambered face. Corrosion and some carbon deposits were found around the spark plug threads, gasket, and neck. Spark could not be produced at the leads when the propeller was rotated. The magnetos were then bench tested with no anomalies noted. The propeller and crank shaft could be manually rotated, and crank case and valve train continuity was established. The fuel strainer was full of fuel, and minimal debris was present. The fuel line from the strainer to the engine and the carburetor had no fuel present, and no blockages were found. All fuel samples taken from the system and all system filters were clear of sizeable debris, consistent with avgas, and no water was found. No evidence of any preaccident mechanical malfunctions or failures were found that would have precluded normal engine operation. The airline transport pilot stated that he and the pilot-rated passenger fueled the airplane from his private fuel tank at his floatplane slip before the flight and that the preflight inspection and engine run-up were normal. He was conducting a takeoff from the rear seat with a pilot-rated passenger in the front seat. When the airplane was between about 100 and 200 ft above ground level, the engine started to “sputter” and lose power. The pilot attempted to restore power by cycling the throttle to no avail. Realizing he would not be able to land on the water, he turned the airplane to land on a nearby gravel runway. He asked the pilot-rated passenger to check that the fuel selector valve was in the “on” position, and he responded that it was. He could not recall the impact attitude or the impact itself. The passenger’s statement corroborated the pilot’s statement, but he added that the airplane landed with a nose-high attitude and then banked right. Impact ground scars were evident across a gravel taxiway and a grassy area next to the runway. The airplane sustained substantial damage to the fuselage and wings. The engine was found attached to the airframe and intact, and the fuel and oil lines were secure. Postaccident examination of the engine and fuel system revealed that there was corrosion on the top spark plugs, and no spark could be produced at the leads; however, these were likely caused by the airplane’s exposure to water with the engine cowling off during the 2 months after the accident. No fuel was present in the carburetor or the fuel line from the fuel strainer to the engine. The fuel tanks had sufficient fuel and no water or debris was found in fuel samples from the fuel system or from the pilot’s private fuel tank. One of the propeller blades was found straight with extensive trailing edge impact damage and dirt and grass dried onto the cambered face, indicative of no rotation at impact. No evidence of any preaccident mechanical malfunctions or failures were noted with the engine or airframe that would have precluded normal operation. Based on the evidence, it is likely that fuel was not reaching the engine, which led to fuel starvation and a subsequent total loss of engine power. Source: NTSB Aviation Accident Database Retrieved: 2026-02-12
NTSB Findings
Hierarchical cause / factor breakdown from the FAA bulk avdata database. Each finding tagged C (Cause) or F (Factor).
- — Not determined-Not determined-(general)-(general)-Unknown/Not determined
- — Aircraft-Fluids/misc hardware-Fluids-Fuel-Unknown/Not determined
Verbatim from NTSB's published report. Source file
NTSB_2018_ANC18LA051.txt.
Findings + structured fields enriched from FAA avall.mdb.
Full investigation docket on
data.ntsb.gov ↗.
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