Design and Numerical Investigation to Predict the Flow Pattern of Non-axisymmetric Convergent Nozzle: A Component of Turboexpander

M. Kumar, D. Panda, Rasmikanti Biswal, Suraj K. Behera, R. Sahoo
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引用次数: 1

Abstract

Current work proposes a novel design methodology using curve-fitting approach for a non-axisymmetric airfoil convergent nozzle used in small-sized cryogenic turboexpander. The curves used for designing the nozzle are based on a combination of fifth and third order curve at upper and lower surface respectively. Four different turbulence model such as k-ε, SST, BSL and SSG Reynolds stress turbulence model is used to visualize and compare the fluid flow characteristics and thermal behaviors at various cross-sections. It is interesting to observe that the Mach number obtained at the outlet of the nozzle is highest and temperature drop is maximum for SSG model under similar boundary conditions. It is also observed that the designed nozzle with curve fitting approach is appropriate for impulse type turbine with a small amount of reaction. The key feature of this implementation is to obtain subsonic velocity at the nozzle exit and reduce the irreversible losses through the nozzle, which can affect the performance of a turboexpander.
非轴对称收敛喷管流型预测的设计与数值研究——涡轮膨胀机的一个部件
针对小型低温涡轮膨胀机非轴对称翼型会聚喷管的设计,提出了一种新的曲线拟合设计方法。设计喷管所用的曲线分别是基于上下表面的五阶曲线和三阶曲线的组合。采用k-ε、SST、BSL和SSG四种不同的雷诺应力湍流模型,对不同截面的流体流动特性和热行为进行可视化比较。有趣的是,在相似的边界条件下,SSG模型在喷管出口获得的马赫数最高,温度下降最大。采用曲线拟合方法设计的喷管适用于反应量较小的冲击型水轮机。该方法的关键特点是在喷嘴出口处获得亚音速速度,并减少通过喷嘴的不可逆损失,这些损失会影响涡轮膨胀器的性能。
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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