Aeromechanics Investigation of a Full-Wing Lift-Compounded Slowed Rotor

Vivek Uppoor; Mrinalgouda Patil; Inderjit Chopra

doi:10.4050/JAHS.71.012007

Aeromechanics Investigation of a Full-Wing Lift-Compounded Slowed Rotor

Vivek Uppoor
, Mrinalgouda Patil
, Inderjit Chopra

University of Maryland, College Park

Research output: Contribution to journal › Article › peer-review

Abstract

An aeromechanical analysis of a scaled rotor with lift compounding is conducted to understand the impact of various wing configurations on performance and loads. An assessment of the half-retreating side wing and full-wing configurations is conducted for advance ratios up to 0.7, for two wing incidence angles (4^◦ and 8^◦ ), and three rotor shaft angles (−4^◦, 0^◦,and 4^◦ ). Aircraft performance, blade pitch control angles, blade structural loads, hub vibratory loads, and aerodynamic interactions between the rotor and wing are evaluated using the University of Maryland Advanced Rotorcraft Code (UMARC). Additionally, UMARC coupled rotor-wing analysis is validated with the wind tunnel data of lift and thrust-compounded rotor configurations. The study shows that the half, asymmetric, wing configuration is beneficial for peak vehicle performance (lift-to-drag ratio) due to rotor lift offset, though the full-wing configuration minimizes blade structural loads. Maximizing wing lift sharing minimizes hub vibratory loads.

Original language	English
Article number	012007
Journal	Journal of the American Helicopter Society
Volume	71
Issue number	1
DOIs	https://doi.org/10.4050/JAHS.71.012007
Publication status	Published - Jan 2026
Externally published	Yes

ASJC Scopus subject areas

General Materials Science
Aerospace Engineering
Mechanics of Materials
Mechanical Engineering

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10.4050/JAHS.71.012007

Cite this

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abstract = "An aeromechanical analysis of a scaled rotor with lift compounding is conducted to understand the impact of various wing configurations on performance and loads. An assessment of the half-retreating side wing and full-wing configurations is conducted for advance ratios up to 0.7, for two wing incidence angles (4◦ and 8◦ ), and three rotor shaft angles (−4◦, 0◦,and 4◦ ). Aircraft performance, blade pitch control angles, blade structural loads, hub vibratory loads, and aerodynamic interactions between the rotor and wing are evaluated using the University of Maryland Advanced Rotorcraft Code (UMARC). Additionally, UMARC coupled rotor-wing analysis is validated with the wind tunnel data of lift and thrust-compounded rotor configurations. The study shows that the half, asymmetric, wing configuration is beneficial for peak vehicle performance (lift-to-drag ratio) due to rotor lift offset, though the full-wing configuration minimizes blade structural loads. Maximizing wing lift sharing minimizes hub vibratory loads.",

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AB - An aeromechanical analysis of a scaled rotor with lift compounding is conducted to understand the impact of various wing configurations on performance and loads. An assessment of the half-retreating side wing and full-wing configurations is conducted for advance ratios up to 0.7, for two wing incidence angles (4◦ and 8◦ ), and three rotor shaft angles (−4◦, 0◦,and 4◦ ). Aircraft performance, blade pitch control angles, blade structural loads, hub vibratory loads, and aerodynamic interactions between the rotor and wing are evaluated using the University of Maryland Advanced Rotorcraft Code (UMARC). Additionally, UMARC coupled rotor-wing analysis is validated with the wind tunnel data of lift and thrust-compounded rotor configurations. The study shows that the half, asymmetric, wing configuration is beneficial for peak vehicle performance (lift-to-drag ratio) due to rotor lift offset, though the full-wing configuration minimizes blade structural loads. Maximizing wing lift sharing minimizes hub vibratory loads.

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Aeromechanics Investigation of a Full-Wing Lift-Compounded Slowed Rotor

Abstract

ASJC Scopus subject areas

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