心室辅助装置中剪切应力和基本流量变量的网格诱导数值误差:对血液损伤预测至关重要?

IF 0.5 Q4 ENGINEERING, MECHANICAL
Lucas Konnigk, B. Torner, Sebastian Hallier, M. Witte, F. Wurm
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引用次数: 7

摘要

对于作为心脏支持系统的血泵来说,由于流动引起的血液损伤引起的不良事件仍然是一个严重的问题。通过计算流体动力学(CFD)对血液损伤进行数值预测是设计和优化可靠泵的有用工具。血液损伤预测模型主要基于作用剪切应力,通过在计算网格上求解Navier-Stokes方程来计算。本文的目的是与其他重要流量(如泵的压头)相比,分析空间离散化和相关离散化误差对血泵中剪切应力计算的影响。因此,使用七个非定常雷诺平均Navier-Stokes(URNS)模拟进行了CFD分析。应用两个简单的应力计算指标,使用一种计算数值不确定性的方法来估计离散化对结果的影响,这表明了离散化误差。对于19的最佳网格 × 106个单元,剪切应力的数值不确定性高达20%,而压头显示出较小的不确定性,最大不确定性为4.8%。在与最先进的血泵研究中的网格尺寸相当的网格尺寸上,无法获得速度梯度相关变量的网格独立解。可以得出结论,网格大小对剪切应力计算有重大影响,因此对潜在的血液损伤预测也有重要影响,应始终考虑该误差的量化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Grid-Induced Numerical Errors for Shear Stresses and Essential Flow Variables in a Ventricular Assist Device: Crucial for Blood Damage Prediction?
Adverse events due to flow-induced blood damage remain a serious problem for blood pumps as cardiac support systems. The numerical prediction of blood damage via computational fluid dynamics (CFD) is a helpful tool for the design and optimization of reliable pumps. Blood damage prediction models primarily are based on the acting shear stresses, which are calculated by solving the Navier–Stokes equations on computational grids. The purpose of this paper is to analyze the influence of the spatial discretization and the associated discretization error on the shear stress calculation in a blood pump in comparison to other important flow quantities like the pressure head of the pump. Therefore, CFD analysis using seven unsteady Reynolds-averaged Navier–Stokes (URANS) simulations was performed. Two simple stress calculation indicators were applied to estimate the influence of the discretization on the results using an approach to calculate numerical uncertainties, which indicates discretization errors. For the finest grid with 19 × 106 elements, numerical uncertainties up to 20% for shear stresses were determined, while the pressure heads show smaller uncertainties with a maximum of 4.8%. No grid-independent solution for velocity gradient-dependent variables could be obtained on a grid size that is comparable to mesh sizes in state-of-the-art blood pump studies. It can be concluded that the grid size has a major influence on the shear stress calculation, and therefore, the potential blood damage prediction, and that the quantification of this error should always be taken into account.
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来源期刊
CiteScore
1.60
自引率
16.70%
发文量
12
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