G. Montenegro, Matteo Tamborski, A. Marinoni, A. D. Torre, A. Onorati, S. Marelli
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引用次数: 0
摘要
在这项工作中,3DCell方法已扩展到汽车涡轮增压器压气机的热流体动力学模拟。3DCell是由米兰理工大学(Politecnico di Milano)的作者不断开发的一种方法,它基于一种伪交错跨越式方法,该方法允许将一个通用的3D问题分解为一组在空间上任意定向的一维标量方程。该方程组是根据运动部件的相对旋转框架求解的,而在其他地方则是根据绝对参考解的。在极坐标系统的基础上对该区域进行离散化,确定了进气管、叶轮、无叶扩散器、蜗壳、出口管道五个宏观子区域,并对每个子区域进行了具体的数值处理。扩散器在切向上的动量被建模为角动量守恒,而转子通道被建模为旋转管道,当它们经历相对源时,与叶片交换功和动量。
A quasi 3D approach for the modelling of an automotive turbocharger’s compressor
In this work the 3DCell method has been extended to the thermo-fluid dynamic simulation of an automotive turbocharger’s compressor. The 3DCell, an approach continuously developed by the authors at Politecnico di Milano, is based on a pseudo-staggered leapfrog method that allows to decompose a generic 3D problem in a set of 1D scalar equation arbitrarily oriented in space. The system of equations has been solved referring to a relative rotating framework for the moving components, whereas to an absolute reference elsewhere. The domain has been discretized on a basis of a polar coordinate system, identifying five macro sub-domains, namely the inlet pipe, impeller, vaneless diffuser, volute, outlet pipe, each treated numerically in a specific way. The diffuser’s momentum in the tangential direction has been modelled resorting to the conservation of the angular momentum, while the rotor channels are modelled as rotating pipes that exchange work and momentum with the blades as they experience a relative source...
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