Authors :
C Dilli Babu; S Vinay Kumar Reddy; D Ravi Kiran; N Kalaimani
Volume/Issue :
Volume 8 - 2023, Issue 7 - July
Google Scholar :
https://bit.ly/3TmGbDi
Scribd :
https://tinyurl.com/ycvvbmht
DOI :
https://doi.org/10.5281/zenodo.8217051
Abstract :
This research paper presents the design and
fabrication process of a hoverbike utilizing an
overlapped configuration. The aim of this study is to
explore the feasibility and performance potential of a
hoverbike concept that incorporates overlapping rotors
for enhanced stability, maneuverability, and safety with
2.5 kg payload. The design considerations, structural
analysis, aerodynamic optimization, and fabrication
techniques employed in the development of the
hoverbike are discussed in detail. Experimental tests and
evaluations are conducted to validate the performance
characteristics and assess the feasibility of the proposed
design. The findings demonstrate the potential of the
overlapped configuration in hoverbike design,
highlighting its ability to achieve improved stability and
control, paving the way for advancements in future
hoverbike technologies.
Keywords :
BLDC Motors, Drones, Unmanned Aerial Vehicles, Efficiency, Power-To-Weight Ratio, High RPM Capability, Control, Stability, Noise Reduction, Maintenance, Future Advancements.
This research paper presents the design and
fabrication process of a hoverbike utilizing an
overlapped configuration. The aim of this study is to
explore the feasibility and performance potential of a
hoverbike concept that incorporates overlapping rotors
for enhanced stability, maneuverability, and safety with
2.5 kg payload. The design considerations, structural
analysis, aerodynamic optimization, and fabrication
techniques employed in the development of the
hoverbike are discussed in detail. Experimental tests and
evaluations are conducted to validate the performance
characteristics and assess the feasibility of the proposed
design. The findings demonstrate the potential of the
overlapped configuration in hoverbike design,
highlighting its ability to achieve improved stability and
control, paving the way for advancements in future
hoverbike technologies.
Keywords :
BLDC Motors, Drones, Unmanned Aerial Vehicles, Efficiency, Power-To-Weight Ratio, High RPM Capability, Control, Stability, Noise Reduction, Maintenance, Future Advancements.