Flow deviation and critical choking in transonic turbine cascades operating with non-ideal compressible flows

IF 1.1 Q4 ENGINEERING, MECHANICAL
Francesco Tosto, A. Giuffrè, P. Colonna, M. Pini
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引用次数: 0

Abstract

In this work we examine the flow deviation and its relationship to critical choking, i.e., choking of the meridional component of velocity, in transonic turbine cascades operating with non-ideal compressible flows. To this purpose, a generalized expression of the corrected flow per unit area as a function of both the thermodynamic state and the molecular complexity of the working fluid, the Mach number, and the amount of swirl is derived. The trends of the corrected flow with respect to these quantities are used to infer physical insights on the flow deviation and on the operability of transonic turbine cascades in off-design conditions. Moreover, reduced-order models for the estimation of the flow deviation and the preliminary assessment of the losses have been developed and validated against the results of CFD simulations performed on a representative transonic turbine stator. Results suggest that flows of dense organic vapors exhibit larger deviations than those pertaining to compounds made of simple molecules, e.g., air. Furthermore, transonic turbines expanding dense vapors reach critical choking conditions at lower Mach numbers than the ones operating with simple molecules, and are affected by larger dissipation due to viscous mixing.
非理想可压缩流下跨声速涡轮叶栅的流动偏差和临界堵塞
在这项工作中,我们研究了在非理想可压缩流下运行的跨声速涡轮叶栅中的流动偏差及其与临界阻塞的关系,即速度经向分量的阻塞。为此,导出了单位面积校正流量的广义表达式,该表达式是工作流体的热力学状态和分子复杂性、马赫数和涡流量的函数。修正流量相对于这些量的趋势用于推断在非设计条件下跨声速涡轮叶栅的流量偏差和可操作性的物理见解。此外,还开发了用于估计流量偏差和初步评估损失的降阶模型,并根据在代表性跨声速涡轮机定子上进行的CFD模拟结果进行了验证。结果表明,与由简单分子(如空气)组成的化合物相比,致密有机蒸汽的流动表现出更大的偏差。此外,与使用简单分子的涡轮机相比,膨胀稠密蒸汽的跨声速涡轮机在更低的马赫数下达到临界阻塞条件,并且由于粘性混合而受到更大耗散的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of the Global Power and Propulsion Society
Journal of the Global Power and Propulsion Society Engineering-Industrial and Manufacturing Engineering
CiteScore
2.10
自引率
0.00%
发文量
21
审稿时长
8 weeks
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