NTSB CAROL · Event
Event ANC11LA039
Aircraft involved
Probable cause & findings
The pilot's loss of directional control during landing, which resulted in a runway excursion. Contributing to the accident were the effects of multiple modifications to the main and tailwheel landing gear through the supplemental type certificate and FAA field approval process, which adversely changed their geometry, and resulted in degraded controllability during landing.
Factual narrative
On May 27, 2011, about 1620 Alaska daylight time, a tailwheel-equipped Cessna 170A airplane, N1742D, sustained substantial damage when it veered off the runway during landing at the Wasilla Airport, Wasilla, Alaska. The airplane was operated by the pilot as a visual flight rules (VFR) personal local flight under the provisions of 14 Code of Federal Regulations Part 91, when the accident occurred. The private pilot and sole passenger were not injured. Visual meteorological conditions prevailed, and no flight plan was filed. During a telephone conversation with the National Transportation Safety Board (NTSB) investigator-in-charge (IIC) on May 29, the pilot said when the airplane touched down during a three-point landing, it immediately veered sharply to the left, and exited the runway. She said she was unable to regain control before the airplane collided with a ditch. The left wing and the fuselage received substantial damage during the collision with the ditch. The pilot said she had recently purchased the airplane, and prior to the purchase did not have any experience in a Cessna 170. Since the purchase, she has accumulated about 29 hours of flight time in the 170. The airplane had been modified with Cessna 180 main landing gear, and larger diameter tires. The airplane had been further modified with a "bird dog" tailwheel. She said when the previous owner demonstrated the airplane, he used heavy braking and excessive thrust to get the tailwheel to straighten out. He told her he always did wheel landings as opposed to three point full stall landings. The pilot said after purchasing the airplane, the original tailwheel had been put back on to help with controllability. On July 8, 2011 the tailwheel assembly was examined by the NTSB IIC. The rotational plane of the tailwheel was not horizontal/parallel to the ground. There was a pronounced negative camber (aft tilt downward) in the rotational plane causing the tailwheel to rotate forward when weight was applied. The increased height of the Cessna 180 gear and taller tires added to the negative camber. The tailwheel spring had been extended aft from its normal position (indicated by old clamp marks), which added additional negative camber. Additional Information A review of the airframe logbooks showed four recent major airframe modifications: (1) A main landing gear reinforcement kit was installed under supplemental type certificate (STC) SA2918NM. (2) The main landing gear spring legs and axles were replaced with Cessna model 180 main landing gear leg springs and axles, under the FAA field approval process. Instructions for continued airworthiness were to adjust wheel alignment using the procedure in Cessna Service Letter S.L.N.-56 dated 8-3-1948 or latest revision. (3) The stock 6.00 x 6 tires and tubes were replaced with 8.50 x 6 tires and tubes, under the FAA field approval process. According to the description of work completed, the tundra tire worksheet and test flight for tire adverse effect was completed, however there was no flight test or return to service flight recorded in the airplane's logbook. (4) The airplane's stock tailwheel spring was replaced with a "Bird Dog" spring under the FAA field approval process. The description of work accomplished states that all installation work was done in accordance with the Cessna 170 manual. A Cessna accident investigator told the NTSB IIC that Cessna does not encourage or support the exchange of airplane components between differing models. He further stated that due to the differences in landing gear geometry of the stock airplane models, that airplane specific guidance in the airplane's maintenance manual would not be appropriate to guarantee the continued airworthiness of such a mixed configuration. With respect to the tailwheel installation, the 170 manual does not include the installation of the "bird dog" tailwheel on a 170 model airplane. An engineer from the Anchorage, Alaska, FAA aircraft certification office (ACO) told the NTSB IIC that he concurred with the Cessna investigator's assessment, and said that due to the change in landing gear geometry, each airplane would have to be test flown/taxied for adverse affects, and specific alignment for that airplane ascertained. The appropriate wheel alignment should be annotated in the airplane's airframe logbook. He further stated that to operate properly the tailwheel plane of rotation should be approximately horizontal. An aircraft mechanic whose company was responsible for the change of the main landing gear on the accident airplane, told the IIC his company does quite a few landing gear changes. Per past practice, the company's mechanics align the gear per the maintenance manual for the airplane, without regard for the dimensional changes in the gear. The FAA inspector who signed the FAA 337 form (major repair and alteration) for the exchange of the main landing gear on the accident airplane, told the IIC that the accident airplane was inspected for conformity to best maintenance practices, not engineering. The FAA does not provide guidance for inspections involving the cumulative effect of multiple modifications. The previous owner of the accident airplane said he owned the airplane for about 7 years, and had about 300 hours of flight time in the 170 model. He said after the modifications he did not notice any difference in the airplane's controllability. Civil Air Regulation (CAR) 3.106 The Civil Air Regulation under which the accident airplane was certificated states in part: "The airplane must be satisfactorily controllable and maneuverable during takeoff, climb, level flight, dive and landing with or without power. It must be possible to make a smooth transition from one flight condition to another without an exceptional degree of skill, alertness, or strength on the part of the pilot... ." FAA Advisory Circular (AC) 43-210 Appendix 1, states: "Item 8—Compliance Statement and Compliance Checklist. Before completing the alteration or repair to your aircraft, be aware that after it has been altered or repaired the aircraft must still meet its certification basis. In block 8 you include the proof (data) that it still does. Your compliance statement should explain how your aircraft still meets its certification basis. For example, if you want to modify the wheels of your small airplane, you would need to ensure that the altered wheels still conform to Title 14 of the Code of Federal Regulations (14 CFR) part 23, section 23.731. The compliance checklist will list each affected 14 CFR/Civil Air Regulation (CAR) and indicate how compliance was shown. This checklist is created by the person doing the alteration or repair and should address each section of the regulations applicable to the project. Appendix 2, has a sample compliance checklist format." "Item 9 (in part)—Previous Alterations or Repairs that May be Affected by This Alteration. Look at the aircraft and review its records to determine if there are any modifications, Supplemental Type Certificates (STC), alterations, or repairs that could cause a problem or conflict with the proposed alteration or repair." "Item 10 (in part)—Instructions for Continued Airworthiness (ICA). In this attachment, describe how you will keep the altered or repaired part of the aircraft airworthy. This might include inspections that need to be done each 100 hours or during the annual inspection. These should be specific instructions that include what should be looked at and minimum or maximum measurements of parts for wear or deterioration. Troubleshooting, functional checks, installation and removal procedures, and servicing requirements." Copies of entries from the airplane's airframe logbook, FAA 337 forms, and applicable regulations are contained in the docket for this report. The pilot said that, when the tailwheel-equipped airplane touched down during a three-point landing, it immediately veered sharply to the left and exited the runway. She was unable to regain control before the airplane collided with a ditch. The airplane had recently been purchased, and the pilot did not have any flight time in the make and model prior to the purchase. The airplane had been modified with larger/taller main landing gears, larger diameter tires, and a tailwheel assembly from another model of airplane. The pilot said that when the previous owner demonstrated the airplane, he used heavy braking and excessive thrust to get the tailwheel to straighten out. He told her he always did wheel landings as opposed to three-point full stall landings. A postaccident examination of the airplane revealed that the rotational plane of the tailwheel was not horizontal/parallel to the ground. There was a pronounced negative camber (aft downward tilt), which caused the tailwheel to rotate forward when weight was applied. The tailwheel spring had been extended aft from its normal position, which added additional negative camber. An engineer from the Federal Aviation Administration aircraft certification office said adjustments to the tailwheel should have been made to make the tailwheel's plane of rotation horizontal. An examination of the airplane's airframe logbook revealed that the airplane's landing gear had been modified under a supplemental type certificate and multiple field approvals. The airplane had been inspected for maintenance conformity, but not engineering. Due to the multiple landing gear modifications, it is likely that the airplane's landing characteristics were degraded, requiring greater pilot vigilance and skill, particularly during landing. 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).
- C Personnel issues-Task performance-Use of equip/info-Aircraft control-Pilot - C
- F Personnel issues-Action/decision-Info processing/decision-Understanding/comprehension-Maintenance personnel - F
- F Organizational issues-Support/oversight/monitoring-Oversight-Oversight of reg compliance-FAA/Regulator - F
- F Aircraft-Aircraft systems-Landing gear system-Landing gear steering system-Damaged/degraded - F
Verbatim from NTSB's published report. Source file
NTSB_2011_ANC11LA039.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 (icing, stall, runway excursion, 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.
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The aerospace industry is competing with other industries for a qualified workforce, and many of those competing industries are investing heavily in creating workforce development pipelines.
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Enhanced Prediction of Three-dimensional Finite Iced Wing Separated Flow Near Stall
Icing on three-dimensional wings causes severe flow separation near stall. Standard improved delayed detached eddy simulation (IDDES) is unable to correctly predict the separating reattaching flow due…
- NASA NTRS 2019 · Contractor Report (CR)
An Evaluation of an Analytical Simulation of an Airplane with Tailplane Icing by Comparison to Flight Data
This report presents the assessment of an analytical tool developed as part of the NASA/FAA Tailplane Icing Program. The analytical tool is a specialized simulation program called TAILSM4 which was de…
- NASA NTRS 2019 · Technical Publication (TP)
NASA/FAA Tailplane Icing Program: Flight Test Report
This report presents results from research flights that explored the characteristics of an ice-contaminated tailplane using various simulated ice shapes attached to the leading edge of the horizontal …
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