RESEARCH OF THE VORTEX FLOWS INFLUENCE ON THE NPP ELEMENTS

O. Mitrofanova, A. Bayramukov, O. Ivlev, D. Urtenov, A. Fedorinov, A. Sorokin
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Abstract

The mechanisms of generation of stable large-scale eddies and flow swirling in complex channels of the 1st and 2nd circuits of transport nuclear power plants (NPP) are revealed. An analysis is given of the influence of vortex formation and flow swirling processes on failures in NPP systems. It is shown that with a complex geometry of the channels of the pipe systems of the thermohydraulic tract and the reactor plant (RP), the unauthorized swirl arising in certain dynamic modes can lead to the effect of blocking the flow caused by the swirl flow crisis. It has been established that the phenomenon of the crisis is accompanied by the generation of low-frequency acoustic vibrations and large pressure losses required to form a recirculation flow zone, which prevents the flow of fluids in complex channels of the nuclear power plant. In the presented work, the manifestation of a swirling flow crisis is considered by examples of modeling the processes of hydrodynamics and heat transfer in the channels of steam generators and the pressure compensation system of transport nuclear power plants. It is shown that the generation of stable vortex formations in the elements of the NPP equipment of the integral type can be directly related to the mechanism of excitation of hazardous vibroresonance effects. Methods for improving the design of pipe systems of steam generating plants are proposed to increase their thermal-hydraulic efficiency and vibration resistance.
涡旋流动对NPP元件影响的研究
揭示了运输核电站一回路和二回路复杂通道内稳定大尺度涡流和流旋的产生机理。分析了核动力核电厂系统中涡流的形成和旋流过程对失效的影响。研究结果表明,由于热工通道和反应堆装置管道系统的通道几何形状复杂,在某些动力模式下产生的非许可涡流会导致涡流流动危机造成的阻塞效应。已经确定,危机现象伴随着形成再循环流动区所需的低频声振动和大压力损失的产生,从而阻止了核电站复杂通道中流体的流动。在本工作中,通过对蒸汽发生器通道中的流体力学和传热过程以及运输核电站的压力补偿系统进行建模,考虑了漩涡流动危机的表现形式。结果表明,整体式核电站装置元件中稳定涡的产生与危险振共振效应的激发机制有直接关系。提出了改进蒸汽发电厂管道系统设计的方法,以提高其热水效率和抗振性。
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