Power requirements of vertical flight in the dronefly

Chong Shen; Mao Sun

doi:10.1016/S1672-6529(14)60115-3

Power requirements of vertical flight in the dronefly

Chong Shen^*
, Mao Sun

^*Corresponding author for this work

School of Aeronautic Science and Engineering

Beihang University

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

11 Scopus citations

Abstract

Power requirements in vertical flight in the dronefly (Eristarlis tenax; also known as hoverfly) are studied using the method of computational fluid dynamics. The flow solution provides the aerodynamic forces and torques; the inertial torques due to the acceleration of the wing-mass are computed analytically. From the aerodynamic and inertial torques, the mechanical power is obtained. It has been shown that at hovering flight, the specific power with 100% elastic energy storage is 43.51 W·kg^-1 and that without elastic energy storage is 60.12 W·kg^-1. During vertical flight, the specific power increases with the ascending ratio K (ratio of the ascending velocity to the tip velocity); it is proportional to K to the power of about 1.37. When flying upward at an ascending ratio of about 0.3, the power required is the same as that when the insect carries a load of about 50% of its weight.

Original language	English
Pages (from-to)	227-237
Number of pages	11
Journal	Journal of Bionic Engineering
Volume	12
Issue number	2
DOIs	https://doi.org/10.1016/S1672-6529(14)60115-3
State	Published - 1 Apr 2015

Keywords

Flight balance
Flight power
Insect
Navier-Stokes simulation
Upward flying

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10.1016/S1672-6529(14)60115-3

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title = "Power requirements of vertical flight in the dronefly",

abstract = "Power requirements in vertical flight in the dronefly (Eristarlis tenax; also known as hoverfly) are studied using the method of computational fluid dynamics. The flow solution provides the aerodynamic forces and torques; the inertial torques due to the acceleration of the wing-mass are computed analytically. From the aerodynamic and inertial torques, the mechanical power is obtained. It has been shown that at hovering flight, the specific power with 100\% elastic energy storage is 43.51 W·kg-1 and that without elastic energy storage is 60.12 W·kg-1. During vertical flight, the specific power increases with the ascending ratio K (ratio of the ascending velocity to the tip velocity); it is proportional to K to the power of about 1.37. When flying upward at an ascending ratio of about 0.3, the power required is the same as that when the insect carries a load of about 50\% of its weight.",

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N2 - Power requirements in vertical flight in the dronefly (Eristarlis tenax; also known as hoverfly) are studied using the method of computational fluid dynamics. The flow solution provides the aerodynamic forces and torques; the inertial torques due to the acceleration of the wing-mass are computed analytically. From the aerodynamic and inertial torques, the mechanical power is obtained. It has been shown that at hovering flight, the specific power with 100% elastic energy storage is 43.51 W·kg-1 and that without elastic energy storage is 60.12 W·kg-1. During vertical flight, the specific power increases with the ascending ratio K (ratio of the ascending velocity to the tip velocity); it is proportional to K to the power of about 1.37. When flying upward at an ascending ratio of about 0.3, the power required is the same as that when the insect carries a load of about 50% of its weight.

AB - Power requirements in vertical flight in the dronefly (Eristarlis tenax; also known as hoverfly) are studied using the method of computational fluid dynamics. The flow solution provides the aerodynamic forces and torques; the inertial torques due to the acceleration of the wing-mass are computed analytically. From the aerodynamic and inertial torques, the mechanical power is obtained. It has been shown that at hovering flight, the specific power with 100% elastic energy storage is 43.51 W·kg-1 and that without elastic energy storage is 60.12 W·kg-1. During vertical flight, the specific power increases with the ascending ratio K (ratio of the ascending velocity to the tip velocity); it is proportional to K to the power of about 1.37. When flying upward at an ascending ratio of about 0.3, the power required is the same as that when the insect carries a load of about 50% of its weight.

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KW - Insect

KW - Navier-Stokes simulation

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Power requirements of vertical flight in the dronefly

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Keywords

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