基于棉线的微流体燃料电池阳极传质特性LB模拟

doi:10.11949/0438-1157.20200019

化工学报 ›› 2020, Vol. 71 ›› Issue (7): 3278-3287.DOI: 10.11949/0438-1157.20200019

基于棉线的微流体燃料电池阳极传质特性LB模拟

穆嫒萍^1,²(),叶丁丁^1,²(),陈蓉^1,²,朱恂^1,²,廖强^1,²

^1.重庆大学低品位能源利用技术及系统教育部重点实验室，重庆 400030
^2.重庆大学能源与动力工程学院工程热物理研究所，重庆 400030

收稿日期:2020-01-06 修回日期:2020-03-03 出版日期:2020-07-05 发布日期:2020-07-05
通讯作者: 叶丁丁
作者简介:穆嫒萍（1995—），女，硕士研究生，muaiping1097@foxmail.com
基金资助:
国家自然科学基金项目(51776026);国家自然科学基金重点国际（地区）合作研究项目(51620105011);重庆大学科研后备拔尖人才培育计划(cqu2017hbrc1B06);重庆市留学人员回国创业创新支持计划创新类(cx2018019);重庆英才计划

LB simulation of anode mass transfer characteristics in cotton thread-based microfluidic fuel cell

Aiping MU^1,²(),Dingding YE^1,²(),Rong CHEN^1,²,Xun ZHU^1,²,Qiang LIAO^1,²

^1.Key Laboratory of Low-grade Energy Utilization Technologies and Systems, Ministry of Education, Chongqing University, Chongqing 400030, China
^2.Institute of Engineering Thermophysics, School of Energy and Powering Engineering, Chongqing University, Chongqing 400030, China

Received:2020-01-06 Revised:2020-03-03 Online:2020-07-05 Published:2020-07-05
Contact: Dingding YE

摘要/Abstract

摘要：

基于棉线的微流体燃料电池采用棉线作为流道，无须外部泵、易于微型化，是便携式微流体设备非常有前景的电源，但其性能受阳极燃料传质的限制。本文采用格子Boltzmann方法研究基于棉线的微流体燃料电池阳极耦合电化学反应的传质特性，通过构建三维的棉线流道数值模型，计算得到该流道内燃料的速度及浓度分布，并讨论燃料的进口浓度及流量对该电池阳极性能及传质特性的影响。计算结果表明：阳极极化曲线与实验结果吻合较好；燃料在棉线内部的流速较低，在不同阳极过电位下，燃料浓度沿流动方向均降低，且过电位越大降低得越多；进口燃料浓度越高时，平均电流密度越高，阳极性能升高；随着进口燃料流量的增加，棉线与反应界面接触部位的浓度与其他区域浓度之间的差异增大，而进口流量较低时，该浓度的差异较小且流道后段的浓度较低。

关键词: 微流体学, 燃料电池, 格子动理格式, 格子Boltzmann, 传质, 流动

Abstract:

Cotton threads are employed as flow channels in thread-based microfluidic fuel cells, which eliminates external pumps and benefits for miniaturization, showing a promising power source for portable microfluidic devices. However, the cell performance is limited by the fuel transfer at the anode. To better understand the fuel transfer characteristics coupled with electrochemical reaction at the anode, lattice Boltzmann (LB) method was used for the cotton thread-based microfluidic fuel cell. A three-dimensional numerical model of the cotton thread flow channel was developed and the distributions of velocity and concentration of fuel were calculated. The effects of inlet fuel concentration and flow rate on performance and mass transfer characteristics of anode were also discussed. The results show that LB results agree well with experimental results of the anode polarization curve. The velocity of fuel inside the cotton thread is lower than that in the gaps among threads. The fuel concentration decreases along the flow direction under different anodic over potentials and larger decrement is found at higher anodic over potentials. An increasing average current density is obtained with an increase in the inlet fuel concentration, leading to a better anode performance. Moreover, with an increase in the inlet fuel flow rate, a greater difference in the fuel concentration is observed between the location where the cotton thread contacts with reaction interface and other regions. When the inlet flow is low, the difference in concentration is small and the concentration in the rear part of the flow channel is low.

Key words: microfluidics, fuel cells, lattice kinetic scheme, lattice Boltzmann, mass transfer, flow

中图分类号:

TM 911.4

穆嫒萍, 叶丁丁, 陈蓉, 朱恂, 廖强. 基于棉线的微流体燃料电池阳极传质特性LB模拟[J]. 化工学报, 2020, 71(7): 3278-3287.

Aiping MU, Dingding YE, Rong CHEN, Xun ZHU, Qiang LIAO. LB simulation of anode mass transfer characteristics in cotton thread-based microfluidic fuel cell[J]. CIESC Journal, 2020, 71(7): 3278-3287.

图/表 1

参考文献 32

1	Saarinen V, Himanen O, Kallio T, et al. A 3D model for the free-breathing direct methanol fuel cell: methanol crossover aspects and validations with current distribution measurements[J]. Journal of Power Sources, 2007, 172(2): 805-815.
2	Sundarrajan S, Allakhverdiev S I, Ramakrishna S. Progress and perspectives in micro direct methanol fuel cell[J]. International Journal of Hydrogen Energy, 2012, 37(10): 8765-8786.
3	Ye D D, Zhu X, Liao Q, et al. Two-dimensional two-phase mass transport model for methanol and water crossover in air-breathing direct methanol fuel cells[J]. Journal of Power Sources, 2009, 192(2): 502-514.
4	Zhu Q Y, Gao Y B, Yu B W, et al. Self-priming compartmentalization digital LAMP for point-of-care[J]. Lab on a Chip, 2012, 12(22): 4755-4763.
5	Morier P, Vollet C, Michel P E, et al. Gravity‐induced convective flow in microfluidic systems: electrochemical characterization and application to enzyme‐linked immunosorbent assay tests[J]. Electrophoresis, 2004, 25(21/22): 3761-3768.
6	Zhou C, Mu Y, Yang M C, et al. A gravity-induced flow injection system for surface plasmon resonance biosensor[J]. Talanta, 2013, 112: 95-100.
7	Arun R K, Halder S, Chanda N, et al. A paper based self-pumping and self-breathing fuel cell using pencil stroked graphite electrodes[J]. Lab on a Chip, 2014, 14(10): 1661-1664.
8	Li X, Tian J F, Shen W. Thread as a versatile material for low-cost microfluidic diagnostics[J]. ACS Applied Materials & Interfaces, 2009, 2(1): 1-6.
9	Agustini D, Bergamini M F, Marcolino-Junior L H. Low cost microfluidic device based on cotton threads for electroanalytical application[J]. Lab on a Chip, 2016, 16(2): 345-352.
10	Qin L D, Vermesh O, Shi Q H, et al. Self-powered microfluidic chips for multiplexed protein assays from whole blood[J]. Lab on a Chip, 2009, 9(14): 2016-2020.
11	Agustini D, Bergamini M F, Marcolino-Junior L H. Tear glucose detection combining microfluidic thread based device, amperometric biosensor and microflow injection analysis[J]. Biosensors and Bioelectronics, 2017, 98: 161-167.
12	Caetano F R, Carneiro E A, Agustini D, et al. Combination of electrochemical biosensor and textile threads: a microfluidic device for phenol determination in tap water[J]. Biosensors and Bioelectronics, 2018, 99: 382-388.
13	Liu Z F, Ye D D, Chen R, et al. A woven thread-based microfluidic fuel cell with graphite rod electrodes[J]. International Journal of Hydrogen Energy, 2018, 43(49): 22467-22473.
14	Domalaon K, Tang C, Mendez A, et al. Fabric-based alkaline direct formate microfluidic fuel cells[J]. Electrophoresis, 2017, 38(8): 1224-1231.
15	Wu R, Ye D D, Chen R, et al. A membraneless microfluidic fuel cell with continuous multi-stream flow through cotton threads[J]. International Journal of Energy Research. 2020, 44(3): 2243-2251.
16	Chen S Y, Doolen G D. Lattice Boltzmann method for fluid flows[J]. Annual Review of Fluid Mechanics, 1998, 30(1): 329-364.
17	Joshi A S, Grew K N, Peracchio A A, et al. Lattice Boltzmann modeling of 2D gas transport in a solid oxide fuel cell anode[J]. Journal of Power Sources, 2007, 164(2): 631-638.
18	Chen L, Luan H B, He Y L, et al. Pore-scale flow and mass transport in gas diffusion layer of proton exchange membrane fuel cell with interdigitated flow fields[J]. International Journal of Thermal Sciences, 2012, 51: 132-144.
19	Zhang D, Cai Q, Gu S. Three-dimensional lattice-Boltzmann model for liquid water transport and oxygen diffusion in cathode of polymer electrolyte membrane fuel cell with electrochemical reaction[J]. Electrochimica Acta, 2018, 262: 282-296.
20	Molaeimanesh G R, Bamdezh M A, Nazemian M. Impact of catalyst layer morphology on the performance of PEM fuel cell cathode via lattice Boltzmann simulation[J]. International Journal of Hydrogen Energy, 2018, 43(45): 20959-20975.
21	Seta T, Takegoshi E, Okui K. Lattice Boltzmann simulation of natural convection in porous media[J]. Mathematics and Computers in Simulation, 2006, 72(2/3/4/5/6): 195-200.
22	Gao J F, Xing H L, Tian Z W, et al. Lattice Boltzmann modeling and evaluation of fluid flow in heterogeneous porous media involving multiple matrix constituents[J]. Computers & Geosciences, 2014, 62: 198-207.
23	Yi J, Xing H L. Finite element lattice Boltzmann method for fluid flow through complex fractured media with permeable matrix[J]. Advances in Water Resources, 2018, 119: 28-40.
24	Nithiarasu P, Seetharamu K N, Sundararajan T. Natural convective heat transfer in a fluid saturated variable porosity medium[J]. International Journal of Heat and Mass Transfer, 1997, 40(16): 3955-3967.
25	Vafai K. Convective flow and heat transfer in variable-porosity media[J]. Journal of Fluid Mechanics, 1984, 147: 233-259.
26	Guo Z L, Zhao T S. Lattice Boltzmann model for incompressible flows through porous media[J]. Physical Review E, 2002, 66(3): 036304.
27	Inamuro T. A lattice kinetic scheme for incompressible viscous flows with heat transfer[J]. Philosophical Transactions of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences, 2002, 360(1792): 477-484.
28	Yang X G, Shi B C, Chai Z H. Generalized modification in the lattice Bhatnagar-Gross-Krook model for incompressible Navier-Stokes equations and convection-diffusion equations[J]. Physical Review E, 2014, 90(1): 013309.
29	Lei T M, Meng X H, Guo Z L. Pore-scale study on reactive mixing of miscible solutions with viscous fingering in porous media[J]. Computers & Fluids, 2017, 155: 146-160.
30	Kang Q J, Lichtner P C, Zhang D X. Lattice Boltzmann pore‐scale model for multicomponent reactive transport in porous media[J]. Journal of Geophysical Research: Solid Earth, 2006, 111(B5):B05203.
31	Chen L, Luan H B, Feng Y L, et al. Coupling between finite volume method and lattice Boltzmann method and its application to fluid flow and mass transport in proton exchange membrane fuel cell[J]. International Journal of Heat and Mass Transfer, 2012, 55(13/14): 3834-3848.
32	Bazylak A, Sinton D, Djilali N. Improved fuel utilization in microfluidic fuel cells: a computational study[J]. Journal of Power Sources, 2005, 143(1/2): 57-66.

[1]	周绍华, 詹飞龙, 丁国良, 张浩, 邵艳坡, 刘艳涛, 郜哲明. 短管节流阀内流动噪声的实验研究及降噪措施[J]. 化工学报, 2023, 74(S1): 113-121.
[2]	张义飞, 刘舫辰, 张双星, 杜文静. 超临界二氧化碳用印刷电路板式换热器性能分析[J]. 化工学报, 2023, 74(S1): 183-190.
[3]	晁京伟, 许嘉兴, 李廷贤. 基于无管束蒸发换热强化策略的吸附热池的供热性能研究[J]. 化工学报, 2023, 74(S1): 302-310.
[4]	程成, 段钟弟, 孙浩然, 胡海涛, 薛鸿祥. 表面微结构对析晶沉积特性影响的格子Boltzmann模拟[J]. 化工学报, 2023, 74(S1): 74-86.
[5]	宋瑞涛, 王派, 王云鹏, 李敏霞, 党超镔, 陈振国, 童欢, 周佳琦. 二氧化碳直接蒸发冰场排管内流动沸腾换热数值模拟分析[J]. 化工学报, 2023, 74(S1): 96-103.
[6]	李艺彤, 郭航, 陈浩, 叶芳. 催化剂非均匀分布的质子交换膜燃料电池操作条件研究[J]. 化工学报, 2023, 74(9): 3831-3840.
[7]	王玉兵, 李杰, 詹宏波, 朱光亚, 张大林. R134a在菱形离散肋微小通道内的流动沸腾换热实验研究[J]. 化工学报, 2023, 74(9): 3797-3806.
[8]	陈哲文, 魏俊杰, 张玉明. 超临界水煤气化耦合SOFC发电系统集成及其能量转化机制[J]. 化工学报, 2023, 74(9): 3888-3902.
[9]	何宣志, 何永清, 闻桂叶, 焦凤. 磁液液滴颈部自相似破裂行为[J]. 化工学报, 2023, 74(7): 2889-2897.
[10]	张媛媛, 曲江源, 苏欣欣, 杨静, 张锴. 循环流化床燃煤机组SNCR脱硝过程气液传质和反应特性[J]. 化工学报, 2023, 74(6): 2404-2415.
[11]	代佳琳, 毕唯东, 雍玉梅, 陈文强, 莫晗旸, 孙兵, 杨超. 热物性对混合型CPCMs固液相变特性影响模拟研究[J]. 化工学报, 2023, 74(5): 1914-1927.
[12]	赵健, 周兴超, 夏丹, 董航. 机械搅拌对原油储罐射流加热过程传热特性的影响规律研究[J]. 化工学报, 2023, 74(5): 1982-1999.
[13]	周必茂, 许世森, 王肖肖, 刘刚, 李小宇, 任永强, 谭厚章. 烧嘴偏转角度对气化炉渣层分布特性的影响[J]. 化工学报, 2023, 74(5): 1939-1949.
[14]	范坤阳, 杨景兴, 许海波, 连兴容, 何凤梅, 陈聪慧, 李增耀. 遮光剂掺杂SiO₂气凝胶传热的统一格子Boltzmann模型研究[J]. 化工学报, 2023, 74(5): 1974-1981.
[15]	王皓, 唐思扬, 钟山, 梁斌. MEA吸收CO₂富液解吸过程中固体颗粒表面的强化作用分析[J]. 化工学报, 2023, 74(4): 1539-1548.

基于棉线的微流体燃料电池阳极传质特性LB模拟

LB simulation of anode mass transfer characteristics in cotton thread-based microfluidic fuel cell

RichHTML

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

图/表 1

参考文献 32

相关文章 15

编辑推荐

Metrics

本文评价