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Volume 9 Issue 1
Huang, J., Zhang, L., & Yu, S. (2011). Modeling micro-particle deposition in human upper respiratory tract under steady inhalation. Particuology, 9(1), 39-43. https://doi.org/10.1016/j.partic.2010.04.003
Modeling micro-particle deposition in human upper respiratory tract under steady inhalation
Jianhua Huang a, Lianzhong Zhang a b *, Suyuan Yu c
a School of Physics, Nankai University, Tianjin 300071, China
b State Key Laboratory of Loess and Quaternary Geology, Institute of Earth Environment, Chinese Academy of Sciences, Xi’an 710075, China
c Institute of Nuclear Energy and New Energy Technology, Tsinghua University, Beijing 100084, China
10.1016/j.partic.2010.04.003
Volume 9, Issue 1,
February 2011,
Pages 39-43
Received 23 November 2009, Revised 22 February 2010, Accepted 6 April 2010, Available online 13 December 2010.
E-mail:
zhanglz@nankai.edu.cn
Highlights
Abstract
A representative human upper respiratory tract (URT) with idealized oral region and asymmetric tracheobronchial (TB) airway has been modeled, and laminar-to-turbulent airflow for typical inhalation modes as well as micro-particle transport and deposition has been simulated using CFX10.0 software from Ansys Inc. on a personal computer. The asymmetric TB airway could not be replaced by an extended straight tube as outlet of the oral region while investigating the tracheal airflow field and particle deposition. Compared to an idealized oral airway with an extended straight tube, several differences could be noted: (i) The laryngeal jet extends further down the trachea and inclines towards the anterior wall; (ii) the turbulence level in trachea is less and decays more quickly; (iii) three recirculation zones are visible with intense adverse current after the glottis; (iv) deposition of small particles in trachea is reduced due to lower turbulence. Refined unstructured mesh with densified boundary layer mesh could be a proper substitute for the structured mesh in the human URT model with asymmetric TB airway. Based on the refined unstructured mesh, the physiological structure of uvula in the soft palate is properly simulated in the present human URT model.
Graphical abstract
Keywords
Human upper airway model; Asymmetric tracheobronchial (TB) airway; Particle deposition; Computational fluid-particle dynamic simulations
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