应用OpenFOAM CFD软件模拟动脉瘤和正常胸主动脉血流

IF 1.8 Q3 MECHANICS
Fluids Pub Date : 2023-10-02 DOI:10.3390/fluids8100272
Francesco Duronio, Andrea Di Mascio
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引用次数: 0

摘要

心血管疾病仍然是世界上最致命的疾病之一。了解心血管系统内的血流动力学对于预防这些疾病和分析其生理和生理病理至关重要。CFD模拟在指导临床预测方面非常有效,更重要的是,可以评估常规诊断技术难以测量的物理和临床参数。因此,本研究特别侧重于研究胸主动脉的血流动力学。真实的主动脉几何关于一个健全和患病的病人提出动脉瘤被考虑。使用OpenFOAM c++库进行CFD模拟,采用患者特定的脉动血流波形,并实现动脉流出的Windkessel压力边界条件。初步验证了所采用的方法对数值不确定性和收敛性的评价。然后,将CFD结果与标准诊断技术测量的胸主动脉压力和速度的实验数据进行比较。正常主动脉的血流量也与患者特定主动脉瘤的血流量模式进行了比较。对壁面压力、壁面剪应力和速度分布等参数进行了研究和讨论。该研究强调,主动脉的血液流动受到动脉瘤发作的强烈影响,再循环区域的增长具有潜在的危险。研究结果最终证明了CFD模拟工具如何捕获主动脉流的详细物理特性,是支持心血管系统临床活动的强大工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Blood Flow Simulation of Aneurysmatic and Sane Thoracic Aorta Using OpenFOAM CFD Software
Cardiovascular diseases still represent one of the most deadly pathologies worldwide. Knowledge of the blood flow dynamics within the cardio-vascular system is crucial in preventing these diseases and analysing their physiology and physio-pathology. CFD simulations are highly effective in guiding clinical predictions and, more importantly, allow the evaluation of physical and clinical parameters that are difficult to measure with common diagnostic techniques. Therefore, in particular, this study is focused on investigating the hemodynamics of the thoracic aorta. Real aortic geometries regarding a sane and diseased patient presenting an aneurysm were considered. CFD simulations were performed with the OpenFOAM C++ library using patient-specific pulsatile blood flow waveforms and implementing the Windkessel pressure boundary condition for the artery outflow. The adopted methodology was preliminarily verified for assessing the numerical uncertainty and convergence. Then, the CFD results were evaluated against experimental data concerning pressure and velocity of the thoracic aorta measured with standard diagnostic techniques. The normal aorta’s blood flow was also compared against the pattern regarding the patient-specific aortic aneurysm. Parameters such as wall pressure, wall shear stress (WSS) and velocity distribution were investigated and discussed. The research highlighted that the blood flow in the aorta is strongly affected by the aneurysm onset, with the growth of recirculation zones being potentially hazardous. The outcomes of the investigation finally demonstrate how CFD simulation tools, capturing the detailed physics of the aortic flow, are powerful tools for supporting clinical activities of the cardio-vascular system.
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来源期刊
Fluids
Fluids Engineering-Mechanical Engineering
CiteScore
3.40
自引率
10.50%
发文量
326
审稿时长
12 weeks
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