Litcius/Paper detail

Tip Vortex Effects on Rotor Aeroacoustics via Hybrid Blade Element Momentum Theory–Free Vortex Wake Prediction

Zimo Wang, Qidong Chen, Siyang Zhong

2025AIAA Journal7 citationsDOI

Abstract

During rotor operation, wakes and tip vortices form and convect downstream, generating unsteady velocities on the blade surface, which act as significant noise sources. High-fidelity numerical simulations account for these effects but are computationally expensive, while the rapid predictions based on blade element momentum theory (BEMT) alone cannot capture the fluid mechanisms associated with tip vortex wakes. This paper presents a hybrid BEMT and free vortex wake (FVW) method to compute mean and unsteady flow variables on blade sections. The BEMT solver accommodates arbitrary flow directions, accounting for variations with the rotational phase angle, while the FVW models tip vortex dynamics with initial strength from BEMT computations. Unsteady airfoil theory is applied to compute time-varying loadings in inflight conditions, serving as noise sources for acoustic calculations. The method is validated with a benchmark rotor in hover and axial flow conditions, where wake correction alters thrust but has negligible noise impact. In inflight conditions, the FVW significantly improves prediction accuracy for blade passing frequency harmonics compared to BEMT alone. Near-field velocity and vortex structures also match high-fidelity simulations well. Application to a multirotor vehicle demonstrates the method’s potential for rapid and efficient noise estimation in low-altitude flight scenarios.

Topics & Concepts

AeroacousticsWakeVortexBlade element theoryWake turbulenceBlade element momentum theoryPhysicsRotor (electric)Helicopter rotorVortex sheddingMomentum (technical analysis)MechanicsComputational aeroacousticsClassical mechanicsAerospace engineeringAerodynamicsAcousticsTurbulenceEngineeringTurbine bladeReynolds numberSound pressureEconomicsTurbineQuantum mechanicsFinanceAerodynamics and Acoustics in Jet FlowsAerodynamics and Fluid Dynamics ResearchAcoustic Wave Phenomena Research