Analysis for stress environment in the alveolar sac model.

Ramana M Pidaparti, Matthew Burnette, Rebecca L Heise, Angela Reynolds
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引用次数: 8

Abstract

Better understanding of alveolar mechanics is very important in order to avoid lung injuries for patients undergoing mechanical ventilation for treatment of respiratory problems. The objective of this study was to investigate the alveolar mechanics for two different alveolar sac models, one based on actual geometry and the other an idealized spherical geometry using coupled fluid-solid computational analysis. Both the models were analyzed through coupled fluid-solid analysis to estimate the parameters such as pressures/velocities and displacements/stresses under mechanical ventilation conditions. The results obtained from the fluid analysis indicate that both the alveolar geometries give similar results for pressures and velocities. However, the results obtained from coupled fluid-solid analysis indicate that the actual alveolar geometry results in smaller displacements in comparison to a spherical alveolar model. This trend is also true for stress/strain between the two models. The results presented indicate that alveolar geometry greatly affects the pressure/velocities as well as displacements and stresses/strains.

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肺泡囊模型应力环境分析。
更好地了解肺泡力学是非常重要的,以避免肺损伤的患者进行机械通气治疗呼吸系统疾病。本研究的目的是研究两种不同肺泡囊模型的肺泡力学,一种是基于实际几何形状的肺泡囊,另一种是基于理想的球形几何形状的肺泡囊,采用流固耦合计算分析。通过流固耦合分析对两种模型进行分析,估计机械通风条件下的压力/速度和位移/应力等参数。流体分析的结果表明,两种肺泡的几何形状对压力和速度给出了相似的结果。然而,从耦合流固分析中获得的结果表明,与球形肺泡模型相比,实际肺泡几何形状导致的位移更小。这一趋势也适用于两个模型之间的应力/应变。结果表明,肺泡的几何形状对压力/速度、位移和应力/应变有很大的影响。
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