N280F

HISTORY OF FLIGHTOn October 25, 2019, about 1541 mountain daylight time, an Enstrom 280F helicopter, N280F, was substantially damaged when it was involved in an accident near Jordan Valley, Oregon. The pilot was fatally injured, and the pilot-rated passenger sustained serious injuries. The helicopter was operated as a Title 14 Code of Federal Regulations Part 91 personal flight.

According to the passenger, the intent of the flight was to fly from their home base of Caldwell Industrial Airport (EUL), Caldwell, Idaho, toward the Owyhee Mountain Range and Reservoir, a trip they had taken multiple times before. Upon her arrival at the airport that afternoon, the pilot had already moved the helicopter out of the hangar. A short time later, they boarded and taxied to the local fueling facility, where the pilot serviced the helicopter with the addition of 22.5 gallons of fuel.

The passenger stated that the departure was to the southwest and was uneventful, and after arriving over the Owyhee Mountain Range, they observed some wild horses. The pilot performed an orbit over the horses while the passenger took photos (See figure 1, inset). Once complete, they proceeded toward the southwest.

A few minutes later, the pilot calmly stated that the "rpm" was low. Due to the tone of his voice, the passenger was not initially concerned, and continued to look out of the window; however, a short time later, the pilot appeared to have become nervous and began manipulating (“working”) the collective control.

There was no change in the sound or feel of the helicopter, but when the passenger looked at the instrument panel, one of the needles that she was used to seeing in the green zone was just to the left of that normal position. The helicopter then rapidly descended, yawed right, and struck the ground right side down.

Family members became concerned when neither occupant returned home that evening and contacted local law enforcement. The wreckage was located the following morning.

Automatic Dependent Surveillance-Broadcast (ADS-B) flight track data of the entire flight indicated that the helicopter maintained a terrain clearance of between 350 and 900 ft above ground level (agl) after departure as it approached the mountain range, while maintaining a groundspeed of about 100 mph. As it entered the range, the helicopter continued to climb as the ground speed slowed to 85 mph. It started to follow the undulating terrain with clearances varying between o and 100 ft agl, until 18 minutes after takeoff and 25 miles southwest of EUL. It then began an orbit at a GPS altitude of about 4,900 ft, which was between 50 and 200 ft agl over terrain.

After completing the orbit, the helicopter departed to the southwest at an altitude of about 5,000 ft mean sea level (msl), and continued for the remaining 2 miles at the same altitude, which corresponded to terrain clearance of between 0 and 50 ft agl, at a ground speed of about 70 mph.

Figure 1 – ADS-B derived route of flight

PERSONNEL INFORMATIONThe pilot’s logbook was not located; however, he reported 900 total hours of flight experience at the time of his last Federal Aviation Administration (FAA) medical examination on May 20, 2016. The pilot completed the requirements for operation under BasicMed on August 10, 2018.

WRECKAGE AND IMPACT INFORMATIONThe helicopter was located about 500 ft south of the last ADS-B target at an elevation of 4,917 ft msl. The helicopter came to rest on its right side on a heading of about 330° magnetic.

The first identified point of impact was characterized by an area of disrupted earth about 25 ft north of the main wreckage, which contained fragments of canopy plexiglass and cabin contents. A series of imprints just forward of the disruption matched the general outline of the forward section of the landing gear skids, beyond which a series of perpendicular slash marks indicated ground contact of the main rotor blade tips.

All three main rotor blades remained attached to the hub, and all exhibited 30° upward bending damage, along with leading edge and chordwise abrasion. Examination of the airframe and flight controls revealed no evidence of mechanical malfunctions or anomalies that would have precluded normal operation.

The engine sustained minimal damage and there was no evidence of catastrophic internal failure. The engine controls were continuous from their respective control arms to the cabin controls. The inlet air filter was free of obstruction. The dual magneto was intact and undamaged, and the engine-to-magneto timing met the manufacturer’s recommended specifications. The spark plug electrodes were mechanically undamaged, coated in light grey deposits, and displayed normal wear signatures. Five of the engine cooling fan blades had bent about 90° opposite the direction of rotation, and rotational scoring and gouging was observed on the right side of the fan shroud adjacent to the blade tips. Examination of the fuel system revealed no anomalies, and fuel was recovered from both tanks.

The main transmission belt engagement clutch was in the fully engaged position, and there was no apparent damage or significant degradation of the drive belt. The freewheeling unit (overrunning clutch) allowed for transmission rotation in the correct direction. The engine and main rotor tachometer drives were intact and operational. The tachometer was subsequently removed, tested, and disassembled. No mechanical anomalies were noted, and the unit met the original manufacturers performance specifications. The helicopter was not equipped with an audio or visual low rotor-rpm warning system.

The engine’s air induction system was composed of an air filter assembly connected to the fuel injection servo via a flexible intake hose. The servo was connected directly to the compressor section of the turbocharger, the outlet of which forced the air and fuel mixture directly into the engine induction manifold.

The flexible hose was a 3-inch diameter, “Silfab-2” type, constructed of a spring steel helix, bonded between a liner and cover which were both composed of fiberglass fabric impregnated silicone rubber. The outer surface of the hose was double wound with a fiberglass cord.

Detailed examination of the hose revealed that the outer cover and fiberglass cord had abraded, such that the steel helix was visible and protruding over about half of the hose’s length. (see Photos 1 and 2.) In some areas, the helix was visible for more than half of the hose circumference, such that the liner and cover were unsupported and could be flexed inward, partially obstructing the flow.

The air induction system section of the helicopter’s 100hr/annual inspection guide stated: “Inspect the flex duct and fuel servo adapter for condition and security of

installation.”

Photo 1 – Engine air induction hose with steel helix visible at multiple locations

Photo 2 - Engine air induction hose with protruding steel helix

ADDITIONAL INFORMATIONThe Helicopter Performance section of the FAA Helicopter Flying Handbook (FAA-H-8083-21B) discusses the height/velocity diagram, in part:

The diagram shows the combinations of airspeed and height above the ground, which will allow an average pilot to successfully complete a landing after an engine failure.

The shaded area on the lower right is dangerous due to the airspeed and proximity to the ground resulting in dramatically reduced reaction time for the pilot in the case of mechanical failure, or other in-flight emergencies.

Based on the helicopter’s basic empty weight, fuel load, and occupant weight, the gross weight at takeoff was about 2,350 lbs. The height/velocity diagram for 2,350 lbs gross weight, as documented in the helicopter’s operator’s manual, is represented in Figure 2.

Figure 2 – 2,350-lb gross weight height/velocity diagram

The operator’s manual also stated:

When an engine failure occurs at low altitude and low airspeed, sufficient altitude may not be available to increase rotor rpm…

The passenger stated that the flight was performed at a relatively low altitude, but she assumed, at least for the time that they flew around the horses, that the helicopter was about 500 ft agl. She based this assumption on the fact that the pilot utilized an iPad with software that included a terrain feature that would annunciate if the helicopter was below 500 ft agl; she did not hear any such annunciations.

Examination of the iPad revealed that the pilot utilized the ForeFlight application for navigation. According to ForeFlight documentation:

500' AGL Alerts - The 500’ AGL alert is a simple callout that triggers when you descend through 500’ AGL after having been above 1,000’ AGL. The alert will only sound once every 60 seconds and is automatically disabled if your groundspeed is less than 40 knots.

ADS-B data indicated that the helicopter did not fly above 900 ft agl during the flight, therefore the 500’ agl alert would not have been active.

MEDICAL AND PATHOLOGICAL INFORMATIONThe Department of Pathology, Saint Alphonsus Medical Center – Ontario (Oregon), performed the pilot’s autopsy at the request of the Malheur County Medical Examiner. According to the Medical Examiner, the cause of death was multiple traumatic injuries due to helicopter crash, and the manner of death was accident.

No impairing drugs were found in toxicological testing.

SURVIVAL ASPECTSThe helicopter was equipped with a 406 AF-COMPACT emergency locator transmitter (ELT), manufactured by Kannad in accordance with FAA technical standard order (TSO) C126. However, no activation signal was received by the Air Force Rescue Coordination Center (AFRCC) following the accident.

The manufacturers installation instructions state that in helicopter applications, the unit must be installed 45° relative to the yaw axis and mounted to a structural member. The installation instructions further stated that an external antenna must be used and installed on the top of the helicopte...