Large-Eddy and Unsteady Reynolds-Averaged Navier-Stokes Simulations of an Axial Flow Pump for Cardiac Support

Torner, Benjamin; Hallier, Sebastian; Witte, Matthias; Wurm, Frank-Hendrik

doi:10.1115/gt2017-65250

Cited by 11 publications

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“…From a physical point of view, equations (16) and (17) should lead to the same power loss P Loss . If this is fulfilled, it can be verified that the equivalent stresses are properly computed.…”

Section: Methods For the Analysismentioning

confidence: 99%

“…Nowadays, the flow simulations in VADs are commonly conducted using unsteady Reynolds-averaged Navier–Stokes (URANS) methods, in which a great part of the turbulent field is modeled. 17 Furthermore, the viscous shear stresses in the flow field are commonly analyzed using equivalent, scalar representations, 16 , 18–25 which are based on the second invariant I I S = 2 S i j S i j of the strain-rate tensor S i j . 3 These are, for example, the stress definition of Bludszuweit, 26 the van-Mises stresses 27 as well as the direct use of the second invariant 20 in the equivalent stress definition.…”

Section: Introductionmentioning

confidence: 99%

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Influence of turbulent shear stresses on the numerical blood damage prediction in a ventricular assist device

2019

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The blood damage prediction in rotary blood pumps is an important procedure to evaluate the hemocompatibility of such systems. Blood damage is caused by shear stresses to the blood cells and their exposure times. The total impact of an equivalent shear stress can only be taken into account when turbulent stresses are included in the blood damage prediction. The aim of this article was to analyze the influence of the turbulent stresses on the damage prediction in a rotary blood pump’s flow. Therefore, the flow in a research blood pump was computed using large eddy simulations. A highly turbulence-resolving setup was used in order to directly resolve most of the computed stresses. The simulations were performed at the design point and an operation point with lower flow rate. Blood damage was predicted using three damage models (volumetric analysis of exceeded stress thresholds, hemolysis transport equation, and hemolysis approximation via volume integral) and two shear stress definitions (with and without turbulent stresses). For both simulations, turbulent stresses are the dominant stresses away from the walls. Here, they act in a range between 9 and 50 Pa. Nonetheless, the mean stresses in the proximity of the walls reach levels, which are one order of magnitude higher. Due to this, the turbulent stresses have a small impact on the results of the hemolysis prediction. Yet, turbulent stresses should be included in the damage prediction, since they belong to the total equivalent stress definition and could impact the damage on proteins or platelets.

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Section: Methods For the Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Influence of turbulent shear stresses on the numerical blood damage prediction in a ventricular assist device

2019

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“…e CFD simulation was based on FLUENT 17.0. e SST k-ω model was selected as the turbulence model, for the SST k-ω model contains the modified turbulent viscosity formulas and considers the effect of turbulent shear stress; it can simulate the near-wall flow field more accurately and proved to be suitable for blood pump simulation [15]. e expression of the k-ω SST model [28] is shown in (12) and (13), where k is the turbulent kinetic energy, ρ is the fluid density, μ is the dynamic viscosity, ω is the specific dissipation rate, μ t is turbulent eddy viscosity, and F 1 is the blending function, which is used to blend the k-ω model (F 1 � 0) and k-ε model (F 1 � 1), and the model coefficients are as follows: β � 0.075, β * � 0.09, σ k σ k � 2, σ ω � 2, and σ ω2 � 1/0.856. One has…”

Section: Construction Of Test Bench As Shown Inmentioning

confidence: 99%

“…During the process, there will be a shear flow field inside the blood pump, and the red blood cells may rupture under the effect of strong shear flow, thus inducing hemolysis [9,10]. To verify the rationality of blood pump structure and speed design, Computational Fluid Dynamics (CFD) is widely used in the flow field simulation of blood pump [11][12][13]. At present, there are many kinds of research focused on the flow field and hemolysis analysis of the blood pump at the constant rotation speed.…”

Section: Introductionmentioning

confidence: 99%

Shear Stress and Hemolysis Analysis of Blood Pump under Constant and Pulsation Speed Based on a Multiscale Coupling Model

Wang

Tan

2020

Mathematical Problems in Engineering

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Current researches show that the constant speed mode adopted by the existing commercial blood pump may cause damage to the body. The way to solve this problem is to produce pulsating flow by changing the speed of the blood pump’s impeller. But at present, the flow field of the blood pump is not clear, when it changes speed, and the coupling between blood pump and body has not been considered in the simulation of the flow field. A multiscale coupling model combining hemodynamics (0D) and Computational Fluid Dynamics (3D) was established in this paper to solve the problem, and a speed change curve consistent with the ventricular motion was selected. The hemodynamics, shear stress, and hemolysis changes of 6000 rpm at different amplitude (2000, 3000, and 4000 rpm) were simulated, analyzed, and compared with the constant speed (7000 rpm). The results show that the pressure difference obtained by simulation is consistent with the experimental results, and the flow generated by the natural heart still flows through the blood pump, thus changing the working point of the blood pump. When the blood pump works at the changing speed, it could produce more pulsation, and the shear stress and hemolysis in the blood pump increase with the rising of speed and flow. But according to the hemolysis score of a single cardiac cycle, the hemolysis value of the changing speed model at an amplitude of 4000 rpm is only 11.71% higher than that of constant speed at 7000 rpm.

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“…[7][8][9][10] Since computational fluid dynamics (CFD) can simulate the complex flow state of fluid and realize the visualization of the flow field, CFD has been widely used in flow field analysis and structural optimization of blood pumps to solve these problems. [11][12][13][14] Blood is mixed with a large number of red blood cells and white blood cells. At present, there are some models 15 and methods [16][17][18] that can analyze the interaction between particles and fluid from a microperspective.…”

Section: Introductionmentioning

confidence: 99%

Study on the influence of dynamic/static interface processing methods on CFD simulation results of the axial-flow blood pump

Wang

Tan

2020

Advances in Mechanical Engineering

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Computational fluid dynamics is an essential tool for the flow field analysis of the blood pump. The interface processing method between the dynamic/static regions will affect the accuracy of simulation results, but its influence on the simulation results is still unclear. In this study, the axial-flow blood pump was taken as the research object, and the effects of the mixing plane, frozen rotor, and sliding mesh methods on the following results were compared: flux conservation at the interface, hydraulic characteristics, and velocity field distribution. In parallel, the particle image velocimetry experiment was carried out to measure the velocity field of the impeller, the inlet, and the outlet area of the blood pump. The results show that the above methods have significant differences in flux conservation between the impeller and the back vane. The average surface energy flux’s error of frozen rotor and sliding mesh are 0.7% and 0.72%, respectively, while the mixing plane method reaches 3.6%. This nonconservative transfer affects the distribution of the downstream velocity field, and the velocity field predicted by the mixing plane at the outlet is quite different. It is suggested to use the frozen rotor method and the sliding mesh method in the simulation of the blood pump.

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Large-Eddy and Unsteady Reynolds-Averaged Navier-Stokes Simulations of an Axial Flow Pump for Cardiac Support

Cited by 11 publications

References 0 publications

Influence of turbulent shear stresses on the numerical blood damage prediction in a ventricular assist device

Influence of turbulent shear stresses on the numerical blood damage prediction in a ventricular assist device

Shear Stress and Hemolysis Analysis of Blood Pump under Constant and Pulsation Speed Based on a Multiscale Coupling Model

Study on the influence of dynamic/static interface processing methods on CFD simulation results of the axial-flow blood pump

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