Importance of Body Stance in Fog Droplet Collection by the Namib Desert Beetle

Importance of Body Stance in Fog Droplet Collection by the Namib Desert Beetle

The fog-basking behavior of the , a beetle species living in the coastal regions of the Namibian desert, has recently caught the attention of the engineering community, as suggesting a viable biomimetic approach to address the problem of harvesting water in arid regions of the globe. Previous resear...

Full description

Saved in:
Bibliographic Details
Published in:Biomimetics (Basel, Switzerland) Vol. 4; no. 3; p. 59
Main Authors: Chakrabarti, Unmeelan, Paoli, Roberto, Chatterjee, Souvick, Megaridis, Constantine M
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 28-08-2019
MDPI
Subjects:
Approximation
Boundary layers
Coastal zone
computational fluid dynamics
Computer applications
droplet collection efficiency
Fluid flow
fluid flow patterns
Fog
fog basking
Freshwater resources
Mimicry
Namib desert beetle
Reynolds number
Simulation
Velocity
Namib Desert
Namib desert beetle
fog basking
computational fluid dynamics
droplet collection efficiency
fluid flow patterns
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The fog-basking behavior of the , a beetle species living in the coastal regions of the Namibian desert, has recently caught the attention of the engineering community, as suggesting a viable biomimetic approach to address the problem of harvesting water in arid regions of the globe. Previous research has focused on observation and analysis of the beetle's elytron properties and how these affect fog-collection rates. The head stance taken by the when fog basking is well documented. However, how this stance affects droplet collection has not been studied up to now. The present paper addresses this problem from a computational fluid dynamics perspective, where three-dimensional numerical simulations are used to characterize the fog flow properties around a simplified geometry mimicking the beetle's body. The simulations employ two-way coupling between the gas flow and the dispersed fog phase to account for feedback effects of fog droplets on the carrier fluid (air), and assume that droplets are captured after hitting the elytron surface. The study considers several combinations of free-stream velocity and droplet volume fraction. The analysis reveals that there is a range of head-stance angles, corresponding to an inclination of the beetle between 35 deg and 45 deg with respect to the horizon, that maximizes water collection on the beetle's back, in qualitative agreement with observations in nature and laboratory experiments. A rationale is proposed to explain this phenomenon, finding that the specific head stance corresponds to the maximum residence time of fluid particles above the beetle's elytron surface. This, in turn, designates the maximum likelihood for water droplets to be captured in the boundary layer developing over the beetle and subsequently hit the surface where they get captured. The results reveal the importance of the fluid flow pattern around the beetle's body in addition to the microphysical properties of the elytron when reliable predictions of the water droplet collection efficiency are sought.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ANL 4J-30361-0030A
USDOE
ISSN:2313-7673
2313-7673
DOI:10.3390/biomimetics4030059