NTSB CAROL · Event
Event CEN24LA184
Registry · N669A
FAA Aircraft Registry record.
Make / Model
PIPER PA-22
Year of manufacture
1951 · 73 years old at event
Engine
LYCOMING 0-290 SERIES (140 hp)
Seats / Engines
4 seats · 1 engine
Last airworthiness date
19560409
ADS-B equipped
Yes — Mode-S A8D5A8
Registrant of record
LEPPERT JAMES J
Source: FAA Aircraft Registry (releasable master file).
Aircraft involved
Probable cause & findings
The pilot’s failure to properly inspect and sump the fuel system before the flight and the maintenance personnel’s inadequate maintenance of the fuel system which resulted in fuel starvation and the subsequent loss of engine power due to the contamination of the right tank fuel gascolator and fuel lines.
Factual narrative
On May 13, 2024, at 1007 central daylight time, a Piper PA-22 airplane, N669A, was substantially damaged when it was involved in an accident near Enderlin, North Dakota. The pilot and two passengers sustained minor injuries. The airplane was operated as a Title 14 Code of Federal Regulations Part 91 personal flight. According to the pilot, she departed Edgeley Municipal Airport (51D) in Edgeley, North Dakota, and flew to Sky Haven Airport (5N4), Enderlin, North Dakota, where she performed two landings. After the second landing, she taxied to the parking area and shut down the airplane. Two passengers boarded the airplane, and the pilot started the engine, performed a run-up, took-off, flew around the traffic pattern once, and landed. After landing, she taxied back to the parking area, the passengers disembarked, and two more passengers boarded the airplane. The pilot took off to perform another circuit in the traffic pattern. Shortly after takeoff, while in a climb and about 100 to 200 ft agl, the engine started to run rough. The pilot turned on the carburetor heat and there was a slight engine power improvement, but then the engine started to run rough again, and the airplane started to descend. About 50 ft agl, the engine lost power and the pilot made an off-airport landing. Upon touchdown, the nosewheel dug into the ground and the airplane flipped inverted. The airplane sustained substantial damage to the left wing, rudder, and engine mount. A review of a carburetor ice chart revealed that the temperature, 53°F, and the dewpoint, 39°F, at the time of the accident were conducive to carburetor ice, but only at cruise power setting and not at a climb power setting. The pilot stated that on the day of the accident, both fuel tanks were filled to maximum capacity (18 gallons per fuel tank) before leaving 51D. She also stated that she was operating solely on the right fuel tank and had flown for a total of about 1 hour when the accident occurred. The left and right fuel tanks drain individually of each other according to the position of the fuel selector valve. The performance chart in the manufacturer’s owner’s handbook states that fuel consumption is about 4.5 to 11 gallons per hour. The owner’s handbook cautions against operating solely on the right fuel tank in a climb if fuel in the right tank is below 1/3 capacity. A postaccident examination of the engine and fuel system revealed no anomalies with the engine that would have precluded normal operation. Upon examining the right tank gascolator strainer housing and bowl, debris and sediment were found (figure 1, 2, & 3). The fuel lines going to and coming out of the fuel strainer contained the same build up and deposits that were found in the fuel bowl. According to the manufacturer, the gascolator should be checked frequently for water or sediment. Additionally, the manufacturer’s inspection report, which meets the requirements for Federal Aviation Regulations Part 43 Maintenance, Preventive Maintenance, Rebuilding, and Alterations, stated that the right tank filter bowl should be drained and cleaned at least every 90 days. The airplane owner said that he assumed the strainer that was under the right front seat was part of the brake system. He was unaware that it was a quick drain gascolator for the right fuel tank and he never sumped that drain. The airframe and powerplant mechanic who performed the three prior annual inspections on the airplane did not return the investigator’s phone call; accordingly, the investigation was unable to determine if he used the manufacturer’s inspection report checklist. According to the pilot, shortly after takeoff about 200 ft above ground level (agl), the engine started to run rough. The pilot turned on the carburetor heat and there was a slight improvement in engine performance, but then the engine lost all power. The pilot made an off-airport landing. Upon touchdown, the nosewheel dug into the ground and the airplane flipped inverted. The airplane sustained substantial damage to the left wing, rudder, and engine mount. A postaccident examination of the engine revealed no anomalies that would have precluded normal operation. Examination of the fuel system revealed that the gascolator and bowl for the right tank rear fuel line were full of sediment and debris. Additionally, the fuel lines going to and coming out of the gascolator contained the same deposits that were found in the fuel bowl. The airplane owner said that he assumed the strainer that was under the right front seat was part of the brake system. He was unaware that it was a quick drain gascolator for the right fuel tank and he never sumped that drain. It could not be determined when maintenance personnel last inspected the gascolator. The pilot reported that she flew a total of about 1 hour before the loss of power occurred and had been operating solely on the right fuel tank. Each fuel tank held 18 gallons of fuel and operated independently of each other depending on fuel selector valve selection. Fuel consumption was between 4.5 to 11 gallons per hour, so it is possible there was only about 7 gallons of fuel remaining in the right fuel tank. Although the owner’s handbook cautioned that operating solely on the right fuel tank should only be done if operating in straight and level flight and when the right fuel tank is at 1/3 capacity or lower, the right fuel tank likely contained more than 1/3 its capacity. The sediment and debris clogging the gascolator filter bowl and fuel lines for the right tank’s rear fuel line likely prevented fuel from flowing freely to the engine, which resulted in a loss of engine power due to fuel starvation. 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).
- — Personnel issues-Task performance-Maintenance-Scheduled/routine maintenance-Maintenance personnel
- — Aircraft-Aircraft oper/perf/capability-Performance/control parameters-Descent/approach/glide path-Not attained/maintained
- — Aircraft-Fluids/misc hardware-Fluids-Fuel-Fluid condition
- — Personnel issues-Task performance-Inspection-Preflight inspection-Pilot
Verbatim from NTSB's published report. Source file
NTSB_2024_CEN24LA184.txt.
Findings + structured fields enriched from FAA avall.mdb.
Full investigation docket on
data.ntsb.gov ↗.
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Related research
What the literature says.
Academic papers and agency reports matching this event's aircraft type or causal vocabulary (fuel starvation, maintenance). Sourced from NASA NTRS, NTSB Safety Studies, FAA CAMI, AOPA Air Safety Institute, Embry-Riddle Scholarly Commons, arXiv, and the Semantic Scholar academic graph.
- Embry-Riddle Scholarly Commons 2026 · Journal article (IJAAA)
From Reactive to Predictive: A hybrid Trust-Mediated Adoption Framework for Data-Driven Maintenance in Distributed-Authority Aviation Environments
Modern aviation maintenance operates within increasingly data-intensive technological environments, yet the operational integration of predictive maintenance into routine decision-making remains incon…
- Semantic Scholar 2025 · Article (Applied Sciences)
Decision-Making Framework for Aviation Safety in Predictive Maintenance Strategies
The implementation of predictive maintenance (PM) in aviation presents unique challenges due to strict safety requirements, complex operational environments, and regulatory constraints.
- Embry-Riddle Scholarly Commons 2024 · Journal article (JAAER)
Low-Resource Automatic Speech Recognition Domain Adaptation – A Case-Study in Aviation Maintenance
With timeliness and efficiency being critical in the aviation maintenance industry, the need has been growing for smart technological solutions that optimize and streamline the different underlying ta…
- Embry-Riddle Scholarly Commons 2024 · Journal article (JAAER)
A New Trajectory in UAV Safety: Leveraging Reinforcement Learning for Distance Maintenance Under Wind Variations
In the field of aviation, safety is a critical cornerstone, and the operation of Unmanned Aerial Vehicle (UAV) systems is deeply connected with this principle.
- Embry-Riddle Scholarly Commons 2024 · Journal article (IJAAA)
Just Culture in Aviation: A Metaphorical Study on Aircraft Maintenance Students
Just Culture, a sub-dimension of safety culture, has been a prominent and debated topic in aviation safety in recent years.
- Embry-Riddle Scholarly Commons 2024 · Journal article (IJAAA)
Performance PRISM: A Comprehensive Framework For Performance Measurement In Aircraft Maintenance
Aircraft maintenance is governed by rigorous safety requirements and high operational complexity, demanding robust performance measurement frameworks to ensure optimal maintenance practices.
Browse the full corpus — academia portal ↗