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管状三维计算喉模型中假声带对喉流阻的影响

The Effect of False Vocal Folds on Laryngeal Flow Resistance in a Tubular Three-dimensional Computational Laryngeal Model.

作者信息

Xue Qian, Zheng Xudong

机构信息

Department of Mechanical Engineering, University of Maine, Orono, Maine..

Department of Mechanical Engineering, University of Maine, Orono, Maine.

出版信息

J Voice. 2017 May;31(3):275-281. doi: 10.1016/j.jvoice.2016.04.006. Epub 2016 May 10.

DOI:10.1016/j.jvoice.2016.04.006
PMID:27178452
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5104676/
Abstract

OBJECTIVE

The current study used a three-dimensional (3D) computational laryngeal model to investigate the effect of false vocal folds (FVFs) on laryngeal flow resistance.

METHOD

A 3D, tubular shaped computational laryngeal model was designed with a high level of realism with respect to the human laryngeal anatomy. Two cases, one with the FVFs and the other without the FVFs, were created in the numerical simulation to compare the laryngeal flow behaviors.

RESULTS AND CONCLUSION

The results were discussed in a comparative manner with the previous two-dimensional (2D) computational model. On the one hand, the results demonstrated the similar mechanism as observed in the 2D model that the presence of the FVFs suppressed the deflection of the glottal jet and in doing so, reduced the mixing-related minor loss in the supraglottal region. On the other hand, the 3D flow was more stable and straighter, so the effect of FVFs on suppressing the jet deflection in the 3D model was not as prominent as in the 2D model. Furthermore, the presence of the FVFs also increased the friction-related major loss due to the increased velocity gradient in the restricted flow channel. Therefore, it was hypothesized that the final effect of the FVFs on flow resistance is the combined effect of the reduced mixing-related minor loss and increased friction-related major loss, both of which are highly related to the gap between the FVFs.

摘要

目的

本研究使用三维(3D)计算喉模型来研究假声带(FVFs)对喉流阻的影响。

方法

设计了一个三维管状计算喉模型,在人体喉解剖结构方面具有高度的逼真度。在数值模拟中创建了两种情况,一种有假声带,另一种没有假声带,以比较喉的流动行为。

结果与结论

结果与之前的二维(2D)计算模型进行了比较讨论。一方面,结果表明与二维模型中观察到的机制相似,即假声带的存在抑制了声门射流的偏转,从而减少了声门上区域与混合相关的局部损失。另一方面,三维流动更稳定、更直,因此假声带在三维模型中对抑制射流偏转的作用不如在二维模型中突出。此外,由于受限流动通道中速度梯度的增加,假声带的存在也增加了与摩擦相关的主要损失。因此,据推测,假声带对流动阻力的最终影响是与混合相关的局部损失减少和与摩擦相关的主要损失增加的综合作用,这两者都与假声带之间的间隙高度相关。

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