Deposition of non-spherical microparticles in the human upper respiratory tract 被引量：4

Deposition of non-spherical microparticles in the human upper respiratory tract

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摘要 We investigated the deposition pattern of microparticles with different particle diameters, shape factors, and initial flow conditions in a realistic human upper respiratory tract model. We identified a close relationship between the deposition fraction and the particle shape factor. The deposition fraction of the particles decreased sharply with increasing particle shape factor because of the decreasing drag force. We also found that the deposition varied at different positions in the upper respiratory tract. At low shape factors, the highest fraction of particles deposited at the mouth and pharynx. However, with increasing shape factor, the deposition fraction in the trachea and lungs increased. Moreover, for a given shape factor, larger particles deposited at the mouth and pharynx, which indicates that the deposition fraction of microparticles in the human upper respiratory tract is affected first and foremost by particle inertia as well as by the drag force. We investigated the deposition pattern of microparticles with different particle diameters, shape factors, and initial flow conditions in a realistic human upper respiratory tract model. We identified a close relationship between the deposition fraction and the particle shape factor. The deposition fraction of the particles decreased sharply with increasing particle shape factor because of the decreasing drag force. We also found that the deposition varied at different positions in the upper respiratory tract. At low shape factors, the highest fraction of particles deposited at the mouth and pharynx. However, with increasing shape factor, the deposition fraction in the trachea and lungs increased. Moreover, for a given shape factor, larger particles deposited at the mouth and pharynx, which indicates that the deposition fraction of microparticles in the human upper respiratory tract is affected first and foremost by particle inertia as well as by the drag force.

作者 Lixing Jia Lianzhong Zhang Suyuan Yu

机构地区 School of Physics Institute of Nuclear and New Energy Technology

出处《Particuology》 SCIE EI CAS CSCD 2018年第1期185-189,共5页 颗粒学报（英文版）

关键词 Particle deposition Non-spherical microparticles Human upper airway Shape factor Particle deposition Non-spherical microparticles Human upper airway Shape factor

分类号 TQ325.7 [化学工程—合成树脂塑料工业] TS255.3 [轻工技术与工程—农产品加工及贮藏工程]

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参考文献3

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共引文献14

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