Share:


Determination of loads in the ultralight helicopter blades

    Vitaly Dudnik Affiliation

Abstract

The article describes research that was carried out on coaxial a single-seat ultralight helicopter Rotorschmiede VA-115 which is manufactured by German firm RS Helikopter GmbH. The purpose of the work was to determine the blades’ loads necessary for further blade fatigue analysis and ground bench tests. The methodology for the load determination consisted of deformation measurements using strain gauges in various flight modes from hovering to maximum speed flight, including climb, descent, acceleration, and braking. Ultralight helicopters occupy the smallest cost niche and, as a rule, full-fledged fatigue studies are not performed for such helicopters. The requirements for ultralight helicopters are also quite loyal, allowing them to pass such experiments. Analysis of the data shows that the amplitude of bending moments on the lower rotor is higher by 1.2 to 2 times the value on the upper rotor. The absolute maximum value of the bending moment is significantly greater at the minimum weight, although the oscillation amplitude becomes smaller. The presented data can be useful for designers of ultralight and UAV helicopters with teetering hinge rotors.

Keyword : ultralight helicopter, main rotor, blade, flight, tests

How to Cite
Dudnik, V. (2023). Determination of loads in the ultralight helicopter blades. Aviation, 27(4), 242–247. https://doi.org/10.3846/aviation.2023.20236
Published in Issue
Nov 28, 2023
Abstract Views
301
PDF Downloads
399
Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

References

Aleksandrin, Y., Butochnikov, I., Chedrik, V., Kudryashov, A., & Uskov, V. (2007). Computational maintenance of rotorcraft fatigue testing by advanced program tools. In 33rd European Rotorcraft Forum (pp. 1–22). ERF. https://dspace-erf.nlr.nl/server/api/core/bitstreams/cd22b69c-e337-4127-800b-532624e9391c/content

Cooke, A., & Fitzpatrick, E. (2002). Helicopter test and evaluation. Blackwell Publishing.

Deutsche Flugsicherung. (2019). Bekanntmachung von Lufttüchtigkeitsforderungen für Ultraleichthubschrauber LTF – ULH vom 28.02.2019. https://www.dulv.de/sites/default/files/Downloads/ltf%20ul-hubschrauber%202019-02-28%20nfl%202-460-19.pdf

Dudnik, V., & Karabut, V. (2023) Ultralight and very light helicopter rotor data. Transactions on Aerospace Research, 271(2), 17–24. https://doi.org/10.2478/tar-2023-0008

Feil, R., Rinker, M., & Hajek, M. (2017). Flight testing of a coaxial ultralight rotorcraft. In 73rd American Helicopter Society Annual Forum. AHS. https://www.researchgate.net/publication/319618214_Flight_Testing_of_a_Coaxial_Ultralight_Rotorcraft

Grebennikov, A., Losev, L., & Timchenko, A. (2013). Proektirovanie legkikh vertoletov. KhAI.

Kargaev, M., & Ignatkin, Y. (2019). On the design of a helicopter rotor blades exposed to the wind flow. In 45th European Rotorcraft Forum (pp. 1–10). ERF. https://dspace-erf.nlr.nl/server/api/core/bitstreams/198dece2-cd27-47ff-bbf8-1ec4d4bbc2ef/content

Losev, L., Zaitsev, V., & Plankowski, S. (2007). Konstruktsia sverkhlegkikh vertolёtov. KhAI.

Mikheev, R. (1987). Letnye prochnostnye ispytania vertoliotov. Mashinostroenie.

Mil, M. (1968). Helicopters. Calculation and design (Vol. II). Vibration and Dynamic Stability. NASA.

Petrosian, E. (2004). Aerodinamika soosnykh vertoletov. Poligon-Press.

Rapp, C., & Wedemeyer, P. (2000). Measurement of in-flight rotor blade loads of an autogyro. In 26 European Rotorcraft Forum (pp. 100.1–100.8). ERF. https://dspace-erf.nlr.nl/items/a6ef96c4-b131-4fdd-95ee-6dfb7d6ad90e