CFD Simulation of Orifice Flow in Orifice-type Liquid Distributor 被引量：2

CFD Simulation of Orifice Flow in Orifice-type Liquid Distributor

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摘要 In this study,a suitable CFD(computational fluid dynamics)model has been developed to investigate the influence of liquid height on the discharge coefficient of the orifice-type liquid distributors.The orifice flow in different diameters and liquid heights has been realized using the shear stress transport(SST)turbulence model and the Gamma Theta transition(GTT)model.In the ANSYS CFX software,two models are used in conjunction with an automatic wall treatment which allows for a smooth shift from a wall function(WF)to a low turbulent-Re near wall formulation(LTRW).The results of the models coupled with LTRW are closer to the experimental results compared with the models with WF,indicating that LTRW is more appropriate for the prediction of boundary layer characteristics of orifice flow.Simulation results show that the flow conditions of orifices change with the variation of liquid height.With respect to the turbulence in orifice,the SST model coupled with LTRW is recommended.However,with respect to the transition to turbulence in orifice with an increase in liquid height,the predictions of GTT model coupled with LTRW are superior to those obtained using other models. In this study, a suitable CFD（computational fluid dynamics）model has been developed to investigate the influence of liquid height on the discharge coefficient of the orifice-type liquid distributors.The orifice flow in different diameters and liquid heights has been realized using the shear stress transport（SST）turbulence model and the Gamma Theta transition（GTT）model.In the ANSYS CFX software, two models are used in conjunction with an automatic wall treatment which allows for a smooth shift from a wall function（WF）to a low turbulent-Re near wall formulation（LTRW）.The results of the models coupled with LTRW are closer to the experimental results compared with the models with WF, indicating that LTRW is more appropriate for the prediction of boundary layer characteristics of orifice flow.Simulation results show that the flow conditions of orifices change with the variation of liquid height.With respect to the turbulence in orifice, the SST model coupled with LTRW is recommended.However, with respect to the transition to turbulence in orifice with an increase in liquid height, the predictions of GTT model coupled with LTRW are superior to those obtained using other models.

作者 Yu Hongfeng Li Xingang Sui Hong Li Hong

机构地区 School of Chemical Engineering and Technology National Engineering Research Center of Distillation Technology

出处《China Petroleum Processing & Petrochemical Technology》 SCIE CAS 2013年第3期70-78,共9页 中国炼油与石油化工（英文版）

基金 the financial support from the National Basic Research Program of China(No.2009CB219905) the Program for Changjiang Scholars and Innovative Research Team in University(No.IRT0936) the National Natural Science Foundation of China(No.21176172)

关键词 discharge coefficient orifice-type liquid distributors CFD liquid height 液体分布器 CFD模拟孔板计算流体动力学湍流模型板型液体高度墙面处理

分类号 O35 [理学—流体力学]

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