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Wednesday, February 3, 2021

Turbulence and turbulent flow structures in a ventricular assist device—A numerical study using the large‐eddy simulation

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Turbulence and turbulent flow structures in a ventricular assist device—A numerical study using the large‐eddy simulation

In this article the turbulence and turbulent flow structures in a ventricular assist device (VAD) are investigated in detail. First, the VAD flow is computed using the turbulence resolving large‐eddy simulation method. Then, the turbulent flow state within an axial VAD is globally quantified with a self‐developed evaluation method. Subsequently, local turbulent flow structures are investigated. The structures found are universal and can be expected in every axial blood pump. Finally, the relevance of these structures for the blood damage prediction will be highlighted.


Abstract

Numerical flow simulations that analyze the turbulent flow characteristics within a turbopump are important for optimizing the efficiency of such machines. In the case of ventricular assist devices (VADs), turbulent flow characteristics must be also examined in order to improve hemocompatibility. Turbulence increases the shear stresses in the VAD flow, which can lead to an increased damage to the transported blood components. Therefore, an understanding of the turbulent flow patterns and their significance for the numerical blood damage prediction is particularly important for flow optimizations in VADs in order to identify and thus minimize flow regions where blood could be damaged due to high turbulent stresses. Nevertheless, the turbulence occurring in VADs and the local turbulent structures that lead to increased turbulent stresses have not yet been analyzed in detail in these machines. Therefore, this study aims to investigate the turbulence in an axial VAD in a comprehensive and double tracked way. First, the flow in an axial VAD was computed using the large‐eddy simulation method, and it was verified that the majority of the turbulence was directly resolved by the simulation. Then, the turbulent flow state of the VAD was quantified globally. For this purpose, a self‐designed evaluation method, the power loss analysis, was used. Subsequently, local flow regions and flow structures were identified where significant turbulent stresses prevail. It will be shown that the identified regions are universal and will also occur in other axial blood pumps as well, for example, in the HeartMate II.

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