旋转填充床反应器流体流动可视化研究进展

doi:10.11949/0438-1157.20190614

摘要/Abstract

摘要：

旋转填充床反应器是一种典型过程强化装置，对化工过程中的传质与混合过程具有较好的强化作用。流体流动作为旋转填充床反应器中最为基础的性质，对研究、优化旋转填充床反应器的结构和性能至关重要。光学成像技术与数值模拟作为研究旋转填充床反应器中流体力学性质的重要手段在近年来得到了飞速发展。对近三十年来，旋转填充床反应器可视化研究进行了综述，从早期光学成像开始，在此基础上引入早期计算流体力学模拟，直至现在高速数码摄像可视化和基于真实结构的模拟。对旋转填充床的可视化观测从填料表面逐渐向填料内部发展，对其数值模拟从初步的数学模型发展到包含详细填料几何结构、详细流体特性的流动模拟。现有研究已对填料区、空腔区中的流体流动有了较为详细的描述。

关键词: 旋转填充床, 计算流体力学, 可视化, 流体流动

Abstract:

The rotating packed bed (RPB) reactor is a typical process strengthening device, which has an active effect on the mass transfer and mixing process. The fluid flow behavior as one of the most fundamental property in a rotating packed bed reactor is essential to the study and optimization of the RPB reactor. Optical imaging technology and numerical simulation have been developed rapidly in recent years as important means to study hydrodynamic characteristics in RPB reactors. In this work, the visualization researches of RPB reactor in recent 30 years have been reviewed. The visualization research of RPB gradually develops from the surface of the packing zone to the inside of the packing zone. Up to now, the fluid flow in the packing and cavity zones can be described, but the simulation of mass transfer and mixing processes and accurate visual experiment still need to be developed deeply.

Key words: rotating packed bed, computational fluid dynamics, visual study, fluid flow

中图分类号:

TQ 028.8

刘易, 武威, 罗勇, 初广文, 邹海魁, 陈建峰. 旋转填充床反应器流体流动可视化研究进展[J]. 化工学报, 2019, 70(10): 3663-3676.

Yi LIU, Wei WU, Yong LUO, Guangwen CHU, Haikui ZOU, Jianfeng CHEN. Visual study of fluid flow in rotating packed bed reactors: a review[J]. CIESC Journal, 2019, 70(10): 3663-3676.

图/表 21

图1 旋转填充床反应器的结构

Fig.1 Schematic illustration of rotating packed bed reactor

图2 旋转填充床反应器反应器纵截面（a），旋转填充床反应器中三种典型流型（b），转速400 r/min（c）、900 r/min（d）和1200 r/min（e）条件下液体分布状况[24]

Fig.2 Cross section of RPB (a), three types of liquid flow within RPB (b)，and liquid distribution on 400 r/min (c), 900 r/min (d), 1200 r/min(e)[24]

图3 R-S波纹丝网填料（a）和泡沫镍填料（b）表面的流体流动状况；同步摄像实验装置（c）和典型实时图像（左图为湿填料，右图为干填料）（d）[26]

Fig.3 Liquid flow on surface of R-S wire mesh packing (a) and nickel foam packing (b), experimental setup (c) and typical photos (left: wet packing, right: dry packing) (d)[26]

图4 旋转填充床反应器中气体速度分布[27]

Fig.4 Velocity counter of gas flow inside RPB reactor [27]

图5 旋转填充床反应器中几何结构、速度云图和气体分布不均因子[28]

Fig.5 Geometric structure，contour of velocity and maldistribution factor of RPB reactor[28]

图6 旋转填充床反应器填料区小方块模型[30]

Fig.6 Small square model for packing zone of RPB reactor [30]

图7 旋转填充床反应器几何结构、网格划分、气相流线和液相流线[31]

Fig.7 Geometric structure， grid refragment，gas flow streamline and liquid flow streamline [31]

图8 旋转填充床反应器填料区二维结构和液体分布云图[32]

Fig.8 2D geometric structure and liquid distribution of RPB reactor [32]

图9 液体在旋转填充床反应器空腔区流动形态[33]

Fig.9 Liquid type in cavity zone of RPB[33]

图10 旋转填充床反应器空腔区中典型流形、液体分布状况、拍摄区域及液体运动状况示意图[35,36]

Fig.10 Typical liquid flow pattern of droplet and ligament,liquid distribution, typical images of droplet motion and schematic diagram of droplet motion in cavity zone[35,36]

图11 规整波纹丝网填料[1]

Fig.11 Structured stainless steel wire mesh packing[1]

图12 旋转填充床反应器填料区二维几何结构及液体分布[37]

Fig.12 2D geometry structure and liquid distribution of packing zone of RPB [37]

图13 旋转填充床反应器填料区小方柱模型结构与液体流动形态[38]

Fig.13 Small cube model and liquid flow pattern of RPB packing zone [38]

图14 分段进液式旋转填充床反应器三维气相模拟与内构件优化[40]

Fig.14 3D gas flow simulation and internals optimization of MLI-RPB[40]

图15 基于湿网和干网的多孔介质模型示意图[41,42,43]

Fig.15 Schematic diagram of porous media model based on wet wires and dry wires [41,42,43]

图16 旋转填充床反应器数值模拟发展趋势

Fig.16 Development of RPB reactor numerical simulation

图17 泡沫镍填料旋转填充床反应器填料区中液体分散和流动形态[44]

Fig.17 Liquid distribution and flow pattern in packing zone of RPB reactor with nickel foam packing[44]

图18 泡沫镍填料旋转填充床反应器空腔区中液体分散和流动形态

Fig.18 Liquid distribution and flow pattern in cavity zone of RPB reactor with nickel foam packing

图19 通过高速摄像和CFD模拟对带有3D打印丝网填料的分段进液式旋转填充床内液体流动的研究[47]

Fig.19 Liquid flow investigation in MLI-RPB with 3D printed wire mesh packing

图20 X射线测定旋转填充床反应器持液量实验装置、R-S波纹丝网填料、泡沫镍填料持液量[45]

Fig.20 Experimental setup and liquid hold up of R-S wire mesh packing,nickel foam packing for RPB reactor via X-ray CT[45]

图21 旋转填充床反应器的PIV研究[48]

Fig.21 PIV study of RPB reactor[48]

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