What question did this study set out to answer?

The research aims to explore how swept-tip tiltrotor blades behave under high-speed conditions and the effects of hub configurations on stability.

March 25, 2026

Understanding High-Speed Aeroelastic Stability of Swept-Tip Tiltrotor Blades

Key Points

The research aims to explore how swept-tip tiltrotor blades behave under high-speed conditions and the effects of hub configurations on stability.
Conducted dynamic tests on a 4.75-ft-diameter swept-tip proprotor up to 200 knots.
Collected stability roots, including frequencies and damping for various motion modes.
Measured impacts of gimbaled versus gimbal-locked hubs.
Compared experimental data with predictions from an aeromechanics solver.
Swept-tip blades increased damping in wing chord and torsion modes under locked gimbal conditions.
No significant effect was observed on the beam mode.
Predictions were generally accurate for stability trends, but showed gaps for torsion mode when the gimbal was locked.

Abstract

A 4.75-ft-diameter, dynamically scaled, swept-tip proprotor was tested up to 200 kts. The stability roots (frequencies and damping) were collected for wing-pylon beam, chord, and torsion motions. The impacts of both gimbaled and gimbal-locked hubs were measured. Predictions from an in-house rotor aeromechanics solver were compared with data to understand the stability behavior and identify gaps in prediction capabilities. The data showed that swept-tip blades increased the damping of the wing chord and torsion modes, but only when the gimbal was locked through perturbation of hub pitch and roll moments. There was no significant effect on the beam mode. The comprehensive analysis was able to predict the stability trends generally, except for torsion, particularly when the gimbal was locked.

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Cite This Study

Delgado et al. (Mon,) studied this question.

synapsesocial.com/papers/69c37bd4b34aaaeb1a67e919 https://doi.org/https://doi.org/10.2514/1.c038396

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