Computational Fluid Dynamics Modeling of the Filtration of 2D Materials Using Hollow Fiber Membranes

IF 2.8 Q2 ENGINEERING, CHEMICAL
Arash Elahi, Santanu Chaudhuri
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Abstract

The current study presents a computational fluid dynamics (CFDs) model designed to simulate the microfiltration of 2D materials using hollow fiber membranes from their dispersion. Microfiltration has recently been proposed as a cost-effective strategy for 2D material production, involving a dispersion containing a permeating solute (graphene), a fouling material (non-exfoliated graphite), and the solvent. The objective of the model is to investigate the effects of fouling of flat layered structure material (graphite) on the transmembrane pressure (TMP) of the system and the filtration of the permeating solute. COMSOL Multiphysics software was used to numerically solve the coupled Navier–Stokes and mass conservation equations to simulate the flow and mass transfer in the two-dimensional domain. For the TMP calculations, we used the resistance-in-series approach to link the fouling of the foulants to the TMP behavior. The foulant particles were assumed to form a polarization layer and cake on the membrane surface, leading to the increment of the TMP of the system. We also assumed the wettability of the polymeric membrane’s inner wall increases upon fouling due to the flat layered structure of the foulant, which results in the reduction in the TMP. This approach accurately reproduced the experimental TMP behavior with a Mean Absolute Error (MAE) of 0.007 psi. Furthermore, the permeation of the permeating solute was computed by incorporating a fouling-dependent membrane partition coefficient for these particles. The effects of the concentration polarization and cake formation fouling stages on the membrane partition coefficient were encapsulated into our defined model parameters, denoted as α and β, respectively. This formulation of the partition coefficient yielded permeate concentration profiles, which are in excellent agreement with the experiments. For three feed concentrations of 0.05, 0.1, and 0.3 g/L, our model reproduced the experimental permeate concentration profiles with MAEs of 0.0002, 0.0003, and 0.0022 g/L, respectively. The flexibility of this model enables the users to utilize the size and concentration-dependent α and β parameters and optimize their experimental microfiltration setups effectively.
二维材料中空纤维膜过滤的计算流体动力学建模
目前的研究提出了一个计算流体动力学(cfd)模型,旨在模拟二维材料的微过滤,利用中空纤维膜从它们的分散。微过滤最近被提出作为一种具有成本效益的2D材料生产策略,涉及含有渗透溶质(石墨烯),污垢材料(非剥落石墨)和溶剂的分散体。该模型的目的是研究平面层状结构材料(石墨)的污染对系统跨膜压力(TMP)和渗透溶质过滤的影响。利用COMSOL Multiphysics软件对Navier-Stokes耦合方程和质量守恒方程进行数值求解,模拟二维区域内的流动和传质过程。对于TMP计算,我们使用串联电阻方法将污染物的污染与TMP行为联系起来。假设污染颗粒在膜表面形成极化层和饼状结构,导致系统TMP增大。我们还假设,由于污染物的扁平层状结构,聚合物膜内壁的润湿性在污染时增加,从而导致TMP的减少。该方法精确地再现了实验TMP行为,平均绝对误差(MAE)为0.007 psi。此外,通过结合这些颗粒的依赖于污染的膜分配系数来计算渗透溶质的渗透。浓度极化和成饼污染阶段对膜分配系数的影响被封装到我们定义的模型参数中,分别用α和β表示。该分配系数公式得到的渗透浓度曲线与实验结果非常吻合。当饲料浓度分别为0.05、0.1和0.3 g/L时,模型模拟了MAEs分别为0.0002、0.0003和0.0022 g/L时的实验渗透浓度曲线。该模型的灵活性使用户能够利用大小和浓度相关的α和β参数,并有效地优化他们的实验微滤设置。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ChemEngineering
ChemEngineering Engineering-Engineering (all)
CiteScore
4.00
自引率
4.00%
发文量
88
审稿时长
11 weeks
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