Cheng Shanbao, Olles Mark W, Burger Aaron F, Day Steven W
Rochester Institute of Technology, Rochester, NY 14623 USA.
Mechatronics (Oxf). 2011 Oct;21(7):1163-1169. doi: 10.1016/j.mechatronics.2011.07.010.
In order to improve the performance of a magnetically levitated (maglev) axial flow blood pump, three-dimensional (3-D) finite element analysis (FEA) was used to optimize the design of a hybrid magnetic bearing (HMB). Radial, axial, and current stiffness of multiple design variations of the HMB were calculated using a 3-D FEA package and verified by experimental results. As compared with the original design, the optimized HMB had twice the axial stiffness with the resulting increase of negative radial stiffness partially compensated for by increased current stiffness. Accordingly, the performance of the maglev axial flow blood pump with the optimized HMBs was improved: the maximum pump speed was increased from 6000 rpm to 9000 rpm (50%). The radial, axial and current stiffness of the HMB was found to be linear at nominal operational position from both 3-D FEA and empirical measurements. Stiffness values determined by FEA and empirical measurements agreed well with one another. The magnetic flux density distribution and flux loop of the HMB were also visualized via 3-D FEA which confirms the designers' initial assumption about the function of this HMB.
为了提高磁悬浮轴向流血液泵的性能,采用三维有限元分析(FEA)对混合磁轴承(HMB)的设计进行优化。使用三维有限元分析软件包计算了HMB多种设计变体的径向、轴向和电流刚度,并通过实验结果进行了验证。与原始设计相比,优化后的HMB轴向刚度提高了两倍,电流刚度的增加部分补偿了由此产生的负径向刚度的增加。因此,采用优化后的HMB的磁悬浮轴向流血液泵的性能得到了改善:最大泵速从6000转/分提高到9000转/分(提高了50%)。通过三维有限元分析和经验测量发现,HMB在标称工作位置的径向、轴向和电流刚度呈线性关系。有限元分析和经验测量确定的刚度值彼此吻合良好。还通过三维有限元分析对HMB的磁通密度分布和磁通回路进行了可视化,这证实了设计者对该HMB功能的初步假设。
