管道充水工况下气液两相流瞬态数值模拟

Transient Numerical Modeling of Gas-liquid Two-phase Flow in Water-filling Pipelines

结合k-ε湍流模型,对三维管道充水过程的气液两相流进行了瞬态数值模拟.建立了管道充水过程液相体积分数与时间的数学模型,并对两相流在管道中的流动特性、能量损耗进行分析.模拟结果表明:充水过程中存在分层、段塞、气团、气泡流;气体在管道中以气团、气泡流流型向下游管网流动;气液两相流造成的能量损耗大于单相流,两相流能量消耗增大的原因是存在气液相间相互作用以及流体与管壁摩擦系数的增大;倾斜下降管道剖面水平方向轴向流速对称分布;垂直方向靠近管道顶部与底部分别出现气、液相轴向流速峰值,气液交界处轴向流速最低.

A three-dimensional transient model of water-filling pipelines is solved numerically by using k- ε turbulent model.The paper gives a water-filling mathematical model of liquid volume fraction against time.The characteristics and energy losses in the gas-liquid two-phase flow are also analyzed.The modeling results show that there are four flow regimes,which are stratified,slug,plug and bubbly,in water-filling pipelines.The gas will move to downstream water networks with flow as plug and bubbly flow patterns.The energy of two-phase flow loses more than those of the single-phase flow due to the interaction between the interfaces of gas and liquid and the increasing of average friction factor between the fluid and pipe walls.In inclined downward pipes,the axial velocity profiles in horizontal centerline are symmetrical.In vertical centerline the axial velocity profiles of gas and liquid near the top and the bottom of the pipe appear peaks,respectively.While on the interface of gas and liquid the one appears the slowest.