Experimental and Computational Evaluation of Rotor Induced and Profile Power

SM-2026-VLADA-5190

1/27/2026

Authors
Abstract
Content

The induced and profile power of a hovering rotor was evaluated using experimental and computational methods. Momentum theory principles were coupled with experimental measurements over a range of thrust conditions to characterize the induced and profile power consumption at low Reynolds number conditions ∼ 105. An empirical induced power factor, κi, was extracted to quantify the non-ideal losses. Results show that these losses increase as the Reynolds number reduces, and nearly twice the power is required at Retip = 0.27×105 than the ideal momentum theory prediction. These results were compared with high-fidelity computational fluid dynamics simulations using the partial-pressure field (PPF) force/power decomposition to extract the induced and profile power contributions of the rotor. The PPF method decomposes the static pressure field of a numerical Reynolds-averaged Navier-Stokes solution into Euler and dissipative partial pressure fields. Simulations were performed across a range of thrust conditions, from which the induced power factor and profile drag coefficient,Cd0 , were computed for each simulation from the extracted power contributors.

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Pages
11
Citation
Moore, Z., Silwal, L., Vijayaraj, A., Raghav, V., et al., "Experimental and Computational Evaluation of Rotor Induced and Profile Power," Vertical Lift Aircraft Design and Aeromechanics Specialists Conference, San Jose, California, Jan 2026, San Jose, California, January 27, 2026, .
Additional Details
Publisher
Published
Jan 27
Product Code
SM-2026-VLADA-5190
Content Type
Technical Paper
Language
English