On the feasibility of the Rayleigh cycle for dynamic soaring trajectories

Autor: Giorgio Graziani, Luca Marino, David Alexandre, Renzo Piva, Andre C. Marta
Rok vydání: 2019
Předmět:
0209 industrial biotechnology
Atmospheric Science
Computer science
Physiology
Airspeed
Velocity
02 engineering and technology
Wind
Wind speed
Dynamic soaring
020901 industrial engineering & automation
Wind profile power law
0203 mechanical engineering
Ornithology
Bird Flight
Medicine and Health Sciences
Astrophysics::Solar and Stellar Astrophysics
Wings
Animal
trajectory optimization
Animal Flight
Energy-harvesting
Wind Power
020301 aerospace & aeronautics
Multidisciplinary
Wind power
Wind strength
Physics
Classical Mechanics
Trajectory optimization
Aerodynamics
Drag
Dynamics
Physical Sciences
Bird flight
Medicine
Engineering and Technology
Alternative Energy
dynamic soaring
Research Article
Optimization
Science
Fluid Mechanics
Continuum Mechanics
Birds
Motion
Meteorology
Mechanical Energy
Animals
Aerospace engineering
business.industry
Biological Locomotion
Biology and Life Sciences
Fluid Dynamics
Models
Theoretical
rayleigh cycle
flight dynamics
Energy and Power
Flight
Animal
Earth Sciences
Feasibility Studies
business
Aviation
Zoology
Mathematics
Zdroj: PLoS ONE
PLoS ONE, Vol 15, Iss 3, p e0229746 (2020)
ISSN: 1932-6203
Popis: Dynamic soaring is a flight technique used by albatrosses and other birds to cover large distances without the expenditure of energy, which is extracted from the available wind conditions, as brightly perceived five centuries ago by Leonardo da Vinci. Closed dynamic soaring trajectories use spatial variations of wind speed to travel, in principle, indefinitely over a prescribed area. The application of the concept of closed dynamic soaring trajectories to aerial vehicles, such as UAVs, may provide a solution to improve the endurance in certain missions. The main limitation of dynamic soaring is its dependence on the wind characteristics. More than one century ago, Lord Rayleigh proposed a very simple model, based on the repeated crossing of a step wind profile, presently known as Rayleigh cycle, that provides a clear explanation of the physical phenomenon. The present paper studies the feasibility of closed, single-loop, energy-neutral trajectories for a broad set of wind and vehicle conditions. Through the use of trajectory optimization methods, it was possible to see how the shape of the wind profile, the initial flight conditions and the vehicle constraints influence the required wind strength to perform dynamic soaring trajectories and consequently their feasibility. It was possible to conclude that there are optimal values for the initial airspeed and initial height of the vehicle, that minimize the required wind strength. In addition, it was seen how the structural and aerodynamic constraints of the vehicle affect dynamic soaring at high and low airspeeds respectively. Finally, some new trajectories that can be performed in conditions of excess wind are proposed. The purpose is to maximize the time spent aloft and the path length while maintaining the concept of single-loop, energy-neutral trajectories, making them especially useful for aerial vehicles surveillance applications.
Databáze: OpenAIRE
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