摇摆条件下旋叶式分离器流场及效率的数值模拟研究

Numerical Simulation Study on Swirl Vane Separator under Rolling Motion Condition

  • 摘要: 海洋核动力堆的紧凑式结构设计导致主设备蒸汽发生器的空间尺寸大幅缩减,作为蒸汽发生器中核心部件的汽水分离装置首当其冲。旋叶式分离器是汽水分离装置中的初级分离器,承担着80%以上的汽水分离任务,其性能优劣直接影响到海洋核动力系统的安全性和经济性。本文以旋叶式分离器为研究对象,结合欧拉-欧拉两相流模型和RNG k-ε湍流模型,利用用户自定义函数(UDF)将海洋摇摆产生的附加惯性力以源项的方式添加到动量方程中,同时考虑重力分量的变化,建立了分离器内汽水两相流动与分离的三维数值计算模型,并系统研究了摇摆幅值和摇摆周期对分离器内流场特性和工作性能的影响。结果表明:周期性的摇摆运动会增强分离器内汽水两相流体的湍流交混,进而导致压力场、速度场和液相体积份额分布混乱,特别地,当摇摆幅值为40°、摇摆周期为2 s时达到临界工况,此时分离器内部多个区域出现流体回流现象,严重影响汽水两相分离效果;由摇摆运动产生的附加惯性力会使分离器内压力和速度分布的周期性波动滞后于分离器自身运动1/4周期;在分离筒近壁面区域,液相体积份额的峰值出现在分离器运动到最大倾角时刻;分离效率的周期性波动近似于正弦函数,在未达到临界工况之前,分离效率的波动与分离器的摇摆运动同步。总体上,摇摆幅值越大、摇摆周期越短,对分离器分离性能影响越大。本文结果可为开发先进的海洋核动力堆汽液分离技术提供理论依据和分析模型。

     

    Abstract: The compact design of the marine nuclear power reactor results in a significant reduction in the size of the main equipment, particularly the steam generator. The primary steam-water separator is the core component in this regard. The swirl vane separator is the primary separator in the steam-water separator, responsible for more than 80% of the steam-water separation task. The performance of the marine nuclear power system directly affects its safety and economy. The primary focus of this study centered on the swirl vane separator, employing the Euler-Euler two-phase flow model in conjunction with the RNG k-ε turbulent flow model. Furthermore, an additional inertia force resulting from the rolling motion was integrated into the momentum equation as a source term using user-defined functions (UDF). The impact of varying gravity components was considered, leading to the development of a three-dimensional numerical computational model to analyze the flow and separation of steam and water within the separator. The impact of varying rolling angle and rolling period on the flow properties and operational efficiency of the separator was methodically investigated. The results indicate that the turbulent mixing of the steam-water two-phase fluid within the separator is enhanced by the rolling motion, leading to a chaotic pressure field, velocity field, and distribution of liquid volume fraction. The critical state is observed when the rolling angle reaches 40° and the rolling period is 2 s. This critical state causes fluid backflow in different parts of the separator, greatly affecting the effectiveness of separating the two-phase flow. The additional inertia force from the rolling motion results in periodic pressure and velocity fluctuations within the separator, with a phase delay of one-quarter period compared to the separator’s motion. In the near-wall region of the separation cylinder, the liquid volume fraction reaches its peak when the separator is at its maximum inclination angle. The periodic changes in separation efficiency follow a sinusoidal pattern. Before reaching the critical condition, the variation in separation efficiency corresponds with the rolling motion of the separator. The influence on the separation performance becomes more pronounced with higher rolling magnitude and shorter rolling period.

     

/

返回文章
返回