A fast and scalable mesh generation method of densely packed hollow fibers for membrane separations: Application to direct contact membrane distillation막 분리용 조밀 충전 중공사의 신속 및 확장형 메쉬 생성 방법 : 직접 접촉 증류막에 대한 적용성
- Other Titles
- 막 분리용 조밀 충전 중공사의 신속 및 확장형 메쉬 생성 방법 : 직접 접촉 증류막에 대한 적용성
- Authors
- Kim, Albet S.; Kim, Hyeon-Ju; Moon, Deok-Soo
- Issue Date
- 2월-2021
- Publisher
- ACADEMIC PRESS INC ELSEVIER SCIENCE
- Keywords
- Computational fluid dynamics; Unit-cell meshing; Mesh assembling; Stitching and merging; Hollow fibers; Membrane distillation
- Citation
- JOURNAL OF COMPUTATIONAL PHYSICS, v.427
- Journal Title
- JOURNAL OF COMPUTATIONAL PHYSICS
- Volume
- 427
- URI
- https://www.kriso.re.kr/sciwatch/handle/2021.sw.kriso/169
- DOI
- 10.1016/j.jcp.2020.110042
- ISSN
- 0021-9991
1090-2716
- Abstract
- Modeling research on membrane distillation requires simulations of coupled momentum, mass, and heat transfer phenomena. Hollow fiber modules are preferred in industrial applications due to their high packing ratio, resulting in the number of fibers on the order of O (10(2) - 10(3)) packed in a vessel. In hollow fiber membrane distillation processes, computational fluid dynamics (CFD) simulations of multi-physics require high-quality meshes for accurate calculations. Mesh interfaces between two different phase regions should conform to satisfy continuity conditions of coupled momentum, heat, and mass transfer. Due to the distinct geometric characteristics of HF packing structures, a scalable meshing method is of great necessity but has not been actively researched. This work developed a numerical method to generate hexagonally packed structures of many fibers by forming a hexagonal unit-cell, consisting of the lumen, membrane, and shell regions. Individual cells are made by duplicating a seed cell and packed to create a self-similar, hexagonal packing of hollow fiber membranes for multi-physics CFD simulations. A new theoretical approach was developed to represent the effusion-like convective mass transfer as conductive heat transfer, and our CFD results were in good agreement with experimental observations. Theoretical methods and numerical algorithms developed in this study can contribute to the improved scalability of CFD simulations from lab-scale modules to pilot scale systems. (C) 2020 Elsevier Inc. All rights reserved.
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