Wind Tunnel Testing of Static Aerodynamic and Power Consumption Characteristics of an Octocopter
Wind Tunnel Testing of Static Aerodynamic and Power Consumption Characteristics of an Octocopter
- New search for: G. V. Altamirano
- New search for: J. J. Matt
- New search for: R. C. Busan
- New search for: J. V. Foster
- New search for: G. V. Altamirano
- New search for: J. J. Matt
- New search for: R. C. Busan
- New search for: J. V. Foster
The introduction of multirotor unmanned aircraft systems (UAS) in low-altitude airspace poses significant safety challenges. Further development of advanced aviation systems is needed to realize the full potential of UAS applications, particularly for urban and beyond visual line-of-sight (BVLOS) operations. The NASA System Wide Safety (SWS) project is developing key technologies to mitigate future airspace safety risks involving autonomous aircraft operation in densely populated areas. An important part of these technologies requires flight dynamics and performance models to assess feasible trajectories, power consumption requirements, and operational envelope limitations. To support these efforts, this research seeks to improve the accuracy of multirotor aerodynamic models and investigate stability characteristics relevant to flight safety. This paper presents a recent study of an octocopter vehicle using the NASA Langley 12-Foot Low-Speed Tunnel (LST). Results from isolated-airframe (no propellers) and powered-airframe tests are presented. A one-factor-at-a-time (OFAT) approach was used to explore the effect of propeller advance ratio and vehicle angle of attack on vehicle forces, moments, and power consumption. The results show nonlinear aerodynamic behavior and indicate regions where aerodynamic interaction effects may be significant.
Document information
Wind Tunnel Testing of Static Aerodynamic and Power Consumption Characteristics of an Octocopter
2023
12 pages
Report
No indication
English