Direct numerical simulation of low Reynolds number turbulent air-water transport in fuel cell flow channel 被引量：6

Direct numerical simulation of low Reynolds number turbulent air-water transport in fuel cell flow channel

导出

摘要 With performance improvement of low-temperature fuel cell(FC), high reactant supply and water generation rates may induce air-water turbulence in the FC flow channel. In this research, an air-water turbulent direct numerical simulation(DNS) model is developed to simulate different droplet sizes,locations and interactions in the air-water transport processes comprehensively. It is found that a larger droplet breaks up more easily in turbulence, and a smaller droplet tends to keep lumped. The droplet at corner does not break up because it is away from channel center. The droplet interaction simulations show that the small droplets merge to form slugs, but still keep lumped in turbulence. It is suggested that two conditions need to be satisfied for droplet break up in FC flow channel, one is turbulent flow, and another is that the droplet needs to be large enough and occupy the center region of flow channel to suffer sufficient turbulence fluctuations. The DNS results illustrate some unique phenomena in turbulent flow, and show that the turbulence has significant effect on the air-water flow behavior in FC flow channel. With performance improvement of low-temperature fuel cell （FC）, high reactant supply and water gen- eration rates may induce air-water turbulence in the FC flow channel, In this research, an air-water tur- bulent direct numerical simulation （DNS） model is developed to simulate different droplet sizes, locations and interactions in the air-water transport processes comprehensively, It is found that a larger droplet breaks up more easily in turbulence, and a smaller droplet tends to keep lumped. The droplet at corner does not break up because it is away from channel center, The droplet interaction simulations show that the small droplets merge to form slugs, but still keep lumped in turbulence. It is suggested that two conditions need to be satisfied for droplet break up in FC flow channel, one is turbulent flow, and another is that the droplet needs to be large enough and occupy the center region of flow channel to suf- fer sufficient turbulence fluctuations, The DNS results illustrate some unique phenomena in turbulent flow, and show that the turbulence has significant effect on the air-water flow behavior in FC flow channel,

作者 Zhiqiang Niu Renfang Wang Kui Jiao Qing Du Yan Yin

机构地区 State Key Laboratory of Engines Sunrise Power Co.

出处《Science Bulletin》 SCIE EI CAS CSCD 2017年第1期31-39,共9页 科学通报（英文版）

基金 supported by the National Key Research and Development Program of China (2016YFB0101303) the Key Program of Natural Science Foundation of Tianjin (China) (16JCZDJC30800)

关键词 DNSFuel cell Turbulence Air-water flow 直接数值模拟湍流流动水运输雷诺兹数燃料电池流道空气-水相互作用

分类号 O357.5 [理学—流体力学] TV213 [水利工程—水文学及水资源]

引文网络
相关文献

参考文献3

1Kang Yang Zhaoli Guo.Multiple-relaxation-time lattice Boltzmann model for binary mixtures of nonideal fluids based on the Enskog kinetic theory[J].Science Bulletin,2015,60(6):634-647. 被引量：2
2Shuzhe Li,Rong Chen,Hong Wang,Qiang Liao,Xun Zhu,Zhibin Wang,Xuefeng He.Numerical investigation of the moving liquid column coalescing with a droplet in triangular microchannels using CLSVOF method[J].Science Bulletin,2015,60(22):1911-1926. 被引量：3
3Xiangdong Liu,Chengbin Zhang,Wei Yu,Zilong Deng,Yongping Chen.Bubble breakup in a microfluidic T-junction[J].Science Bulletin,2016,61(10):811-824. 被引量：1

二级参考文献72

1Stone HA, Stroock AD, Ajdari A (2004) Engineering flows in small devices, microfluidics toward a lab-on-a-chip. Annu Rev Fluid Mech 36:381-411.
2Whitesides G, Stroock A (2001) Flexible methods for microflu- idics. Phys Today 54:42-48.
3Juncker D, Schmid H, Drechsler U et al (2002) Autonomous microfluidic capillary system. Anal Chem 74:6139-6144.
4Yao M, Shah G, Fang J (2012) Highly sensitive and miniaturized fluorescence detection system with an autonomous capillary fluid manipulation chip. Micromachines 3:462-479.
5Cordero ML, Rolfsnes HO, Burnham DR (2009) Mixing via thermocapillary generation of flow patterns inside a microfluidic drop. New J Phys 11:075033.
6Okawa D, Pastine S J, Zettl Aet al (2009) Surface tension mediated conversion of light to work. J Am Chem Soc 131:5396-5398.
7Luong TD, Nguyen NT, Sposito A (2012) Thermocoalescence of microdroplets in a microfluidic chamber. Appl Phys Lett 100:254105.
8Daniel S, Chaudhury MK, Chen JC (2001) Fast drop movements resulting from the phase change on a gradient surface. Science 291:633-636.
9Boreyko JB, Chen CH (2009) Self-propelled dropwise conden- sate on superhydrophobic surfaces. Phys Rev Lett 103:184501.
10Sellier M, Nock V, Verdier C (2011) Self-propelling, coalescing droplets. Int J Multiph Flow 37:462-468.

共引文献3

1李宗蔚,任梦柯,宋贝贝,阮诗伦,李征,王新宇.基于Fluent的三维注塑充填界面追踪方法研究[J].塑料工业,2016,44(12):28-32. 被引量：3
2Qiang Liao,Yan-Xia Yang,Xun Zhu,Rong Chen,Qian Fu.Pore-scale lattice Boltzmann simulation of flow and mass transfer in bioreactor with an immobilized granule for biohydrogen production[J].Science Bulletin,2017,62(1):22-30.
3宋祺,杨智,陈颖,罗向龙,陈健勇,梁颖宗.局部几何构型对聚焦流微通道内液滴生成特性的影响[J].化工学报,2020,71(4):1540-1553. 被引量：2

同被引文献24

1马天才,孙泽昌,许思传.质子交换膜燃料电池温度控制仿真模型[J].系统仿真学报,2005,17(3):548-551. 被引量：19
2陈潇,汪茂海,张扬军,张钊.车用燃料电池发动机热管理系统研究[J].车用发动机,2006(6):12-15. 被引量：7
3翟双,周苏,陈凤祥,张传升.质子交换膜燃料电池分布参数模型数值仿真研究进展[J].同济大学学报（自然科学版）,2012,40(6):932-936. 被引量：5
4Chen, Zhen-Qing,Li, Wenbo,Li, Zenghu.Preface[J].Science China Mathematics,2012,55(11):2193-2193. 被引量：24
5陈维荣,朱亚男,李奇,邓惠文,洪志湖.轨道交通用多堆燃料电池发电系统拓扑及系统控制与检测方法综述及展望[J].中国电机工程学报,2018,38(23):6967-6980. 被引量：19
6Changbo Fu,Jie Bao,Liming Chen,Jianjun He,Long Hou,Liang Li,Yanfei Li,Yutong Li,Guoqian Liao,Yongjoo Rhee,Yang Sun,Shiwei Xu,Dawei Yuan,Xiaopeng Zhang,Gang Zhao,Jiarui Zhao,Baojun Zhu,Jianqiang Zhu,Jie Zhang.Laser-driven plasma collider for nuclear studies[J].Science Bulletin,2015,60(13):1211-1213. 被引量：3
7郭爱,陈维荣,刘志祥,李奇.燃料电池机车热管理系统建模和动态分析[J].西南交通大学学报,2015,50(5):953-960. 被引量：12
8Mujian Xia,Dongdong Gu,Guanqun Yu,Donghua Dai,Hongyu Chen,Qimin Shi.Selective laser melting 3D printing of Ni-based superalloy： understanding thermodynamic mechanisms[J].Science Bulletin,2016,61(13):1013-1022. 被引量：15
9Dongdong Gu.Materials creation adds new dimensions to 3D printing[J].Science Bulletin,2016,61(22):1718-1722. 被引量：7
10夏全刚.车用燃料电池发动机水热管理系统探讨[J].汽车实用技术,2018,44(23):17-19. 被引量：3

引证文献6

1Donghua Dai,Dongdong Gu,Reinhart Poprawe,Mujian Xia.Influence of additive multilayer feature on thermodynamics, stress and microstructure development during laser 3D printing of aluminum-based material[J].Science Bulletin,2017,62(11):779-787. 被引量：7
2戴刘亮.燃料电池发动机水热管理仿真分析综述[J].内燃机与配件,2021(3):50-53. 被引量：1
3刘祥荣,蒋宇,张雪霞,陈维荣.质子交换膜燃料电池三维数值仿真研究综述[J].中国电机工程学报,2021,41(21):7352-7369. 被引量：5
4Linhao Fan,Yun Wang,Kui Jiao.Enhancing oxygen transport in the ionomer film on platinum catalyst using ionic liquid additives[J].Fundamental Research,2022,2(2):230-236.
5吕方明,包志铭,王博文,焦魁.气体扩散层侵入流道对燃料电池水管理影响研究[J].化工学报,2024,75(8):2929-2938.
6Niyi Olukayode,Shenrong Ye,Mingruo Hu,Yanjun Dai,Rui Chen,Sheng Sui.A comprehensive review of the modeling of transport phenomenon in the flow channels of polymer electrolyte membrane fuel cells[J].Frontiers of Chemical Science and Engineering,2024,18(8):123-161.

二级引证文献13

1Pei WANG,Jürgen ECKERT,Konda-gokuldoss PRASHANTH,Ming-wei WU,Ivan KABAN,Li-xia XI,Sergio SCUDINO.A review of particulate-reinforced aluminum matrix composites fabricated by selective laser melting[J].Transactions of Nonferrous Metals Society of China,2020,30(8):2001-2034. 被引量：39
2王迪,邓国威,杨永强,陈杰,吴伟辉,张明康.金属异质材料增材制造研究进展[J].机械工程学报,2021,57(1):186-198. 被引量：29
3WANG Di,DENG Guo-wei,YANG Yong-qiang,CHEN Jie,WU Wei-hui,WANG Hao-liang,TAN Chao-lin.Interface microstructure and mechanical properties of selective laser melted multilayer functionally graded materials[J].Journal of Central South University,2021,28(4):1155-1169. 被引量：6
4褚夫众,张曦,黄文静,侯娟,张恺,黄爱军.选区激光熔化铝合金缺陷的形成机制和对力学性能的影响:综述[J].材料导报,2021,35(11):11110-11118. 被引量：16
5张心悦,张海伦,王雷.燃料电池氢循环喷射器性能分析与结构优化[J].仪器仪表学报,2021,42(6):152-160. 被引量：6
6孙峰,苏丹丹,殷宇捷,董小平,李志远,庞彬.PEMFC翅脉流道传质及输出性能分析[J].太阳能学报,2022,43(6):414-419. 被引量：3
7孙峰,苏丹丹,殷宇捷,庞彬,董小平,李志远.泡沫金属流道对PEMFC性能的影响[J].中南大学学报（自然科学版）,2022,53(12):4617-4626. 被引量：1
8刘松.时效温度对激光选区熔化成形AlSi7Mg铝合金显微组织的影响[J].金属热处理,2023,48(7):205-213. 被引量：1
9朱昌隆,王洪泽,郭利萍,唐梓珏,母杰瑞,吴一,黄洁,胡凯明,王浩伟.铝基复合材料激光粉末床熔化增材制造研究现状[J].铸造技术,2023,44(7):583-598. 被引量：3
10余晨帆,王亚飞,赵聪聪,刘伟.激光选区熔化316L不锈钢凝固特征与微观组织结构[J].材料科学与工艺,2023,31(4):24-33. 被引量：3

1米志立,蒋明.大涡模拟在水利中的研究进展[J].邵阳学院学报（自然科学版）,2004,1(1):88-91. 被引量：2
2陈卓,张睿琦,王晓娜.CFD study of flow-diffusion process in Y-shape micromixer[J].Journal of Central South University,2016,23(4):969-974.
3李润,张敬升,雍玉梅,汪洋,杨超.Numerical simulation of steady flow past a liquid sphere immersed in simple shear flow at low and moderate Re[J].Chinese Journal of Chemical Engineering,2015,23(1):15-21. 被引量：2
4陆杭军,弓晓晶,王春雷,方海平,万荣正.Effect of Vibration on Water Transport through Carbon Nanotubes[J].Chinese Physics Letters,2008,25(3):1145-1148.
5S.ASAD,A.ALSAEDI,T.HAYAT.Flow of couple stress fluid with variable thermal conductivity[J].Applied Mathematics and Mechanics(English Edition),2016,37(3):315-324.
6Bojan Niceno,Tilo Lumpp,Pavel Apanasevich,Dirk Lucas.RANS （Reynolds Averaged Navier-Stokes） and LES （Large Eddy Simulations） of the Air-Water TOPFLOW-PTS Experiment[J].Journal of Energy and Power Engineering,2013,7(7):1231-1237.
7Maryiam Javed,T. Hayat,A. Alsaedi.MHD peristaltic flow in an inclined channel with heat and mass transfer[J].International Journal of Biomathematics,2016,9(1):191-205.
8等离子体所低温等离子体制备纳米材料及应用研究取得进展[J].硅酸盐通报,2013,32(8):1619-1619.
9Sun Wei,Gao Zhenghong,Du Yiming,Xu Fang.Mechanism of unconventional aerodynamic characteristics of an elliptic airfoil[J].Chinese Journal of Aeronautics,2015,28(3):687-694. 被引量：6
10Ming Pingjian Zhang Wenping.Numerical Simulation of Low Reynolds Number Fluid-Structure Interaction with Immersed Boundary Method[J].Chinese Journal of Aeronautics,2009,22(5):480-485. 被引量：3

Science Bulletin

2017年第1期

浏览历史

内容加载中请稍等...