Numerical study of the natural convection heat transfer from the neck folds of the frill-neck lizard

doi:10.7523/j.ucas.2022.078

Abstract

Abstract: In this paper, the physical modeling of Chlamydosaurus kingii, a reptile with special heat dissipation structure, was carried out, and the natural convection heat transfer properties of it were numerically studied. It was found that there was only one maximum heat transfer coefficient in the range of 45°~85°, which was obtained at around 65° for the simulation of different field angle adjustment of Chlamydosaurus kingii neck fold. At the same time, by changing the size of Chlamydosaurus kingii neck fold, it was also observed that there was a unique maximum convection heat transfer coefficient in the range of 6.3≤L₀/d≤6.6. In addition, the field angle and area corresponding to the maximum heat transfer rate were close to the natural state of Australian subspecies. Therefore, it can be inferred that the evolution direction of Chlamydosaurus kingii neck fold may be beneficial to improving the natural convection heat transfer rate. Hence, the natural convection between Chlamydosaurus kingii and external environment may be considered as an important reason affecting the evolution direction of Chlamydosaurus kingii neck fold.

Key words: neck folds of the frill-neck lizard, natural convection, $\overline{N u}$ number, numerical simulation

CLC Number:

TK124

JIA Chongxi, WANG Hao, LIU Jie, LU Wenqiang. Numerical study of the natural convection heat transfer from the neck folds of the frill-neck lizard[J]. Journal of University of Chinese Academy of Sciences, DOI: 10.7523/j.ucas.2022.078.

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