O. Golubyatnikov, E. Akulinin, Alexey A. Kolomoets
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引用次数: 0
摘要
本文对变压吸附(PSA)合成气分离氢气净化装置吸附器内固定层颗粒吸附剂内流动的气动结构进行了数值研究。Сomputational实验在COMSOL Multiphysics软件中使用1-D和2-D数学模型计算了用于PSA制氢过程的13X吸附剂体层的速度场。在对吸附剂内气体流动的气动结构计算精度进行评估时,发现使用二维数学模型比一维模型平均提高了1-2%的计算精度。当在PSA装置中使用粒径大于2mm的吸附剂时,由于垂直圆柱形吸附剂中心及其壁上的速度发散增加,使用二维和三维数学模型进行计算是有希望的,速度超过0.3 m/s
CFD MODELING OF FLOW IN A STATIONARY ADSORBENT BED FOR PRESSURE SWING ADSORPTION PROCESS OF HYDROGEN PURIFICATION
The paper presents the results of numerical studies of the aerodynamic structure of the flow in a fixed layer of granular adsorbent in the adsorber of a pressure swing adsorption (PSA) unit for synthesis gas separation and hydrogen purification. Сomputational experiments were conducted in COMSOL Multiphysics software using 1-D and 2-D mathematical models to calculate the velocity field in the bulk layer of the 13X adsorbent for the PSA process of hydrogen purification. When assessing the accuracy of calculating the aerodynamic structure of the gas flow in the adsorbent, it was found that the use of a 2-D mathematical model provides an increase in the accuracy of calculations by an average of ~ 1-2% compared with the 1-D model. It is determined that when using an adsorbent with a particle diameter of more than 2 mm in the PSA unit, the use of 2-D and 3-D mathematical models for calculations is promising at speeds of more than 0.3 m/s, due to an increase in the velocity divergence in the center of the vertical cylindrical adsorber and on its walls