两相流喷射器仿真方法的开发与验证

Hiroaki Nakanishi, Yoshiteru Komuro, Y. Kondo, Koichi Tanimoto
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摘要

两相喷射器是一种不需要泵或电就能产生吸流的装置。两相喷射器内的流动由驱动流和吸力流组成。当驱动流膨胀吹出驱动流喷嘴时,热能势转化为动量,并将其给予吸力流,从而可以在不使用外部动力的情况下诱导流动。在核电站中,两相喷射器可以作为一种装置,在停电的情况下驱动冷却剂流动。驱动流与吸力流的混合在气液界面处伴随蒸发或冷凝,取决于热工水力参数和流量,需要对其进行控制以保持驱动力,但平衡稍有变化就很容易超出工作范围。在寻找和设计操作条件和喷射器配置方面,关于传热和传质的知识很少。本文建立了临界两相流气液界面传热传质模型。为了处理界面同时发生相变的热非平衡两相流,我们在CFD工具中引入了本构方程,例如界面面积浓度的相关性,并根据工作流体的物理性质评估了蒸发系数,这是确定相变速率的重要参数。利用文献中两相喷射器的实验数据,对CFD模拟方法进行了验证。在验证中,比较了驱动流和吸力流的流量以及喷射器内的压力分布。验证了所建立的CFD仿真方法的有效性。
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Development and Validation of Simulation Method for a Two-Phase Flow Ejector
A two-phase ejector is a device to induce a suction flow without pump or electricity. The flow in the two-phase ejector consists of a drive flow and a suction flow. As the driving flow expands blowing out of a drive flow nozzle, the thermal energy potential is converted into momentum, and by giving it to the suction flow, it is possible to induce the flow without using external power. In a nuclear power plant, a two-phase ejector can be utilized as a device to drive coolant flow in the cases of power failure. Mixing of the drive flow and the suction flow accompanied with evaporation or condensation at the gas-liquid interface depends on thermal hydraulic parameters and flow rate, and it is necessary to control them to maintain the driving force, but it can easily come out of operation range with a slight change in balance. There is little knowledge about heat and mass transfer to find and design operating conditions and ejector configurations. In this study, a heat and mass transfer model of the gas-liquid interface in a critical two-phase flow was developed. To handle thermally non-equilibrium two-phase flow with phase changes occurring simultaneously at the interface, we implemented constitutive equations into CFD tool, such as a correlation for interfacial area concentrations, and we evaluated evaporation coefficient, which is an important parameter to determine the phase change rate, based on the physical property of the working fluid. The CFD simulation method was validated using the experimental data in the literature of a two-phase ejector. In the validation, the flow rates of the drive flow and the suction flow, and pressure distribution inside the ejector were compared. Then, the validity of the developed CFD simulation method have confirmed.
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