基于Voronoi分形划分的双孔径多孔材料孔道结构参数化设计

doi:10.19976/j.cnki.43-1448/TF.2022007

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摘要本文提出了一种适用于模拟双孔径多孔介质的孔道结构模型,该模型可独立形成空间均匀分布的大、小尺寸的两种孔径,并在此基础上开发可以生成参数化孔道模型图示及构成体素坐标的面向过程程序。通过划分函数的迭代,从对应几何方法的自相似性引出此模型的一般孔隙度、分形维度、间隙度和比表面积方面的讨论。最后通过面向对象编程,选择工业三维建模软件开发一种可以生成较大规模几何模型文件的技术路线及渗流与电化学仿真应用方法。

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	张禹
	刘如铁
	陈洁
	熊翔
	李浩
	王铸博

关键词 ： Voronoi划分, 分形, 二元孔隙度, 孔道结构, 多孔介质, 多孔电极

Abstract：This research proposed a bimodal porosity structure type providing the ability to individually form evenly distributed pores of two separated sizes. A method of generating structures parametrically was provided, and a process-oriented program was developed outputting diagrams and coordinates. Iterations of tessellation module, causing geometrical self-resemblance, were further discussed from porosity, fractal dimension, lacunarity and specific surface area aspects. Technical routes were introduced for building 3D model files of large complexity in common industrial software’s object-oriented application programming interface and applications in permeability or electrochemistry simulations.

Key words： Voronoi tessellation fractal bimodal porosity porous structure porous media porous electrode

收稿日期: 2022-03-23 出版日期: 2022-07-19

ZTFLH:

TB113

基金资助:国家国际科技合作专项资助项目(2015DFR50580)

通讯作者: 刘如铁,教授,博士。电话：0731-88876566;E-mail: llrrtt@csu.edu.cn; 陈洁,副教授,博士。电话：0731-88876566;E-mail: chenjiecsu@163.com

引用本文:

张禹, 刘如铁, 陈洁, 熊翔, 李浩, 王铸博. 基于Voronoi分形划分的双孔径多孔材料孔道结构参数化设计[J]. 粉末冶金材料科学与工程, 2022, 27(3): 257-266.
ZHANG Yu, LIU Rutie, CHEN Jie, XIONG Xiang, LI Hao, WANG Zhubo. Parametric design of bimodal porosity structure based on Voronoi polygons and fractals. Materials Science and Engineering of Powder Metallurgy, 2022, 27(3): 257-266.

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http://pmbjb.csu.edu.cn/CN/10.19976/j.cnki.43-1448/TF.2022007 或 http://pmbjb.csu.edu.cn/CN/Y2022/V27/I3/257

[1] FOROOZESH J, KUMAR S.Nanoparticles behaviors in porous media: application to enhanced oil recovery[J]. Journal of Molecular Liquids, 2020: 113876.
[2] DIAO K K, ZHAO Y Y.Heat transfer performance of sintered Cu microchannelsproduced by a novel method[J]. International Journal of Heat and Mass Transfer, 2019, 139: 537-547.
[3] EGOROV V, O'DWYER C. Architected porous metals in electrochemical energy storage[J]. Current Opinion in Electrochemistry, 2020, 21: 201-208.
[4] WOOD S, HARRIS A T.Porous burners for lean-burn applications[J]. Progress in Energy & Combustion Science, 2008, 34(5): 667-684.
[5] NIE Z W, LIN Y Y, TONG Q B, et al.Numerical investigation of pressure drop and heat transfer through open cell foams with 3D Laguerre-Voronoi model[J]. International Journal of Heat & Mass Transfer, 2017, 42(2): 969-974.
[6] LOTFI N, FARAHANI T S, YAGHOUBINEZHAD Y, et al.Simulation and characterization of hydrogen evolution reaction on porous NiCu electrode using surface response methodology[J]. International Journal of Hydrogen Energy, 2019, 44(26): 13296-13309
[7] LIU R T, CHEN J, XIONG X.Influence of porogen type and copper powder morphology on property of sintering copper porous materials[J]. Journal of Central South University, 2018, 25(9): 2143-2149.
[8] TANGGARNJANAVALUKUL C, DONPHAI W, WITOON T, et al.Deactivation of nickel catalysts in methane cracking reaction: effect of bimodal meso-macropore structure of silica support[J]. Chemical Engineering Journal, 2015, 262:364-371.
[9] FU X W, LIU J J, DING C F, et al.Building bimodal Structures by a wettability difference-driven strategy for high- performance protein air-filters[J]. Journal of Hazardous Materials, 2021, 415(42): 125742.
[10] LI H, LIU R T, CHEN J, et al.Preparation of nickel porous materials by sintering nickel oxalate and sodium chloride after blending and reduction[J]. Journal of Materials Research and Technology, 2020, 9(3): 3149-3157.
[11] WANG Z B, CHEN J, LIU R T, et al.Preparation of an ultrafine nickel powder by solid-phase reduction with a NaCl separator agent[J]. Advanced Powder Technology, 2020, 31(8): 3433-3439.
[12] AL-KHARUSI A S, BLUNT M J. Network extraction from sandstone and carbonate pore space images[J]. Journal of Petroleum Science and Engineering, 2007, 56(4):219-231.
[13] SURI S.Handbooks in Operations Research and Management Science[M]. Amsterdam: IGI Global, 1995: 425-479.
[14] MEBATSION H K, VERBOVEN P, VERLINDEN B E, et al.Microscale modeling of fruit tissue using Voronoi tessellations[J]. Computers and Electronics in Agriculture, 2006, 52(1/2):36-48.
[15] HAN N, GUO R.Two new Voronoi cell finite element models for fracture simulation in porous material under inner pressure[J]. Engineering Fracture Mechanics, 2019,211:478-494.
[16] GATSONIS N A, SPIRKIN A.A three-dimensional electrostatic particle-in-cell methodology on unstructured Delaunay-Voronoi grids[J]. Journal of Computational Physics, 2009, 228(10): 3742-3761.
[17] MISTANI P, GUITTET A, POIGNARD C, et al.A parallel Voronoi-based approach for mesoscale simulations of cell aggregate electropermeabilization[J]. Journal of Computational Physics, 2019, 380: 48-64.
[18] SHIRRIFF K.Generating fractals from Voronoi diagrams[J]. Computers & Graphics, 1993, 17(2):165-167.
[19] XIAO F, YIN X L.Geometry models of porous media based on Voronoi tessellations and their porosity-permeability relations[J]. Computers & Mathematics with Applications, 2016, 72(2): 328-348.
[20] CAO B W, WANG S L, WEI D, et al.Investigation of the filtration performance for fibrous media: coupling of a semi-analytical model with CFD on Voronoi-based microstructure-Science Direct[J]. Separation and Purification Technology, 2020, 251:117364.
[21] WEJRZANOWSKI T, SKIBINSKI J, SZUMBARSKI J, et al.Structure of foams modeled by Laguerre-Voronoi tessellations[J]. Computational Materials Science, 2013, 67: 216-221.
[22] NIE Z W, LIN Y Y, TONG Q B.Modeling structures of open cell foams[J]. Computational Materials Science, 2017, 131: 160-169.
[23] KHALA M J, HARE C, WU C Y, et al.Density and size-induced mixing and segregation in the FT4 powder rheometer: an experimental and numerical investigation[J]. Powder Technology, 2021, 390: 126-142.
[24] LIU W, TANG G H, SHI Y.Apparent permeability study of rarefied gas transport properties through ultra-tight Voronoi porous media by discrete velocity method[J]. Journal of Natural Gas Science and Engineering, 2020, 74: 103100.
[25] LEI H Y, LI J R, XU Z J, et al.Parametric design of Voronoi-based lattice porous structures[J]. Materials & Design, 2020, 191:108607.
[26] UHLMANN M.Vorono tessellation analysis of sets of randomly placed finite-size spheres[J]. Physica A: Statistical Mechanics and its Applications, 2020, 555: 124618.
[27] HENDERSON N, BRÊTTASJC, SACCO W F. A three- parameter Kozeny-Carman generalized equation for fractal porous media[J]. Chemical Engineering Science, 2010, 65(15): 4432-4442.
[28] WEI W, CAI J C, XIAO J F, et al.Kozeny-Carman constant of porous media: insights from fractal-capillary imbibition theory[J]. Fuel, 2018, 234: 1373-1379.
[29] PINTO E P, PIRES M A, MATOS R S, et al.Lacunarity exponent and Moran index: acomplementary methodology to analyze AFM images and its application to chitosan films[J]. Physica A: Statistical Mechanics and its Applications, 2021, 581: 126192.
[30] XIA Y X, WEI W, LIU Y, et al.A fractal-based approach to evaluate the effect of microstructure on the permeability of two-dimensional porous media[J]. Applied Geochemistry, 2021, 131: 105013.