喷射器激波设计与捕获的数值模拟

2019 16th International Bhurban Conference on Applied Sciences and Technology (IBCAST) Pub Date : 2019-01-01 DOI:10.1109/IBCAST.2019.8667160

A. Zaidi, E. Uddin

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引用次数: 0

摘要

两个会聚发散喷嘴组成的系列称为喷射器;第一或一次喷嘴将高压一次流体加速到低压和超音速。在一次喷嘴末端形成的低压将流体带入二次喷嘴。最终，这两种流体流在等面积截面处相遇，产生激波。然后，扩散器将压力增加到所需的范围。本文采用数值模拟方法对R134a为制冷剂的喷射器的设计和冲击捕获进行了研究。采用k-epsilon湍流模型，采用Reynolds平均Navier Stokes方程(RANS)进行流动分析。首先对每个喷管进行了仿真，然后对引射器进行了综合仿真。在引射器中，压力和速度大小的快速波动表明，在引射器中存在一系列冲击波，导致压力升高。压力和马赫数等高线解释了喷射器二次流体吸入和夹带背后的物理现象。

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Design and Capturing of Shock Wave in Ejector by Numerical Simulations

Series of two convergent-divergent nozzles is called ejector; the first or primary nozzle accelerates high pressure primary fluid to low pressure and at supersonic speed. The low pressure developed at the end of primary nozzle entrains the fluid in the secondary nozzle. Eventually, these two fluid streams meet at constant area section resulting in a shock wave. Afterwards, diffuser increases the pressure to desired range. In this paper, numerical simulations are used for designing and shock capturing in ejector using R134a as a refrigerant. The flow analysis is done by Reynolds averaged Navier Stokes equation (RANS) using k-epsilon turbulence model. At first, simulations are done for each nozzle and later they are combined in case of ejector. In case of ejector, rapid fluctuations in pressure and magnitude of velocity showed that there are series of shock waves that result in increase in pressure in ejector. The pressure and Mach number contours explained the physics behind the suction and entrainment of secondary fluid in ejector.

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2019 16th International Bhurban Conference on Applied Sciences and Technology (IBCAST)

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