In this paper we present a finite-element-based methode for the calculation of the unsteady potential flow in rotor/stator configurations. A numerical algorithm was developed to calculate the two-dimensional flow through a centrifugal volute pump, taking into account the width variation of the volute in the axial direction and the vortex wakes downstream of the impeller blades by a linearized vortex distribution. The pressure field was obtained from the unsteady Bernoulli equation, with the entire configuration of the pump being included in the calculations. For that purpose the computational domain was split into a region containing the rotor and one containing the stationary parts, each region being treated in a different co-ordinate system. The corresponding finite element grids qare matched by an interface consisting of connect elements which move with time. The method is applied to a laboratory centrifugal pump set up at the Von Karman Institute for Fluid Dynamics, which made an experimental validation possible. The total head of the pump and the velocity and pressure fields were computed and analysed for various mass flows. The agreement with the experimental data was satisfactory. The deviation was largest at low mass flow, the maximum deviation in the velocity around the impeller being 10 per cent. The overall behaviour of the pump could be well predicted.
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机译:在本文中,我们提出了一种基于有限元的方法来计算转子/定子配置中的非稳态势流。考虑到蜗壳在轴向上的宽度变化以及通过线性涡旋分布在叶轮叶片下游的涡流唤醒,开发了一种数值算法来计算通过离心蜗壳泵的二维流动。压力场是从不稳定的伯努利方程获得的,计算中包括了整个泵的配置。为此,将计算域划分为一个包含转子的区域和一个包含固定部分的区域,每个区域都在不同的坐标系中进行处理。对应的有限元网格q由包含随时间变化的连接元素组成的接口匹配。该方法应用于由冯卡曼流体动力学研究所(Von Karman Institute for Fluid Dynamics)建立的实验室离心泵,这使得进行实验验证成为可能。计算并分析了泵的总扬程以及速度和压力场,以分析各种质量流量。与实验数据的一致性令人满意。在低质量流量下,偏差最大,叶轮周围的速度最大偏差为10%。泵的整体性能可以很好地预测。
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