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质子交换膜燃料电池内扩散层/流道表面处液态水滴的运动特征 被引量:2

Characteristics of liquid droplet motion at gas diffusion layer/gas flow channel interface in PEM fuel cells
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摘要 针对燃料电池流场内任意选取的特征单元建立二维模型,分析在剪切流作用下附着在扩散层(GDL)/流道(GFC)表面液滴的运动特征,认为液滴运动时迟滞角(液滴运动过程中前进角与后退角间的差值)与液滴高度、气体流速存在着一定关系;而与所选取的特征单元长度无关。模型还有效耦合了实验总结的液滴开始运动的条件关系式,真实反映了液滴开始运动、不断加速追赶及聚并的运动趋势。结果表明:选取矮流道,增大气体流速,采用疏水的GDL增大液滴的不稳定性,同时增加流道表面的亲水性,有利于液滴获得较大加速度,并以拐角流的形式快速从电池内排除。 Two dimensional models based on the typical part in the flow field of PEM fuel cell were presented to analyse the characteristics of liquid droplet motion at the gas diffusion layer(GDL)/gas flow channel(GFC)interface.There were some regular relationships among the contact angle hysteresis(the difference angle between the advancing and the receding angle of moving droplet),the height of the droplet and the velocity of the shear flow,however,the length of the typical part chosen by random had no effect on the result.This model also coupled the condition when the droplets just ran-off from the surface,and reflected the trend of droplet moving,chasing and coalescing.Analysis showed that:lower flow passage,higher fluid velocity and adopting hydrophobic GDL interface to increase the instability of droplets,while using hydrophilic GFC interface to get bigger acceleration were all good ways for removing water from the fuel cell by corner flow.
作者 肖宇 明平文 衣宝廉
机构地区 中国科学院大连化学物理研究所 新源动力有限公司
出处 《化工学报》 EI CAS CSCD 北大核心 2008年第8期2089-2094,共6页 CIESC Journal
关键词 质子交换膜燃料电池 液滴 亲水 疏水 PEM fuel cell droplet hydrophobic hydrophilic
分类号 O646 [理学—物理化学]
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参考文献12

  • 1YiBaolian(衣宝廉).Fuel Cell Principle, Technology and Application (燃料电池——原理技术应用).Beijing :Chemical Industry Press, 2003:160.
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同被引文献27

  • 1杜春雨,史鹏飞,程新群,尹鸽平.质子交换膜燃料电池催化层的有效质子电导率[J].化工学报,2005,56(6):1102-1105. 被引量:2
  • 2王晓东,彭晓峰,张欣欣.水平壁面上液滴吹离的临界风速[J].应用基础与工程科学学报,2006,14(3):403-410. 被引量:7
  • 3Youn Bok-Hee, Huh Chan-Su. Surface degradation of HTV siliconerubber and EPDM used for outdoor insulators under acceleratedultraviolet weathering condition [J]. IEEE Transactions on Dielectricsand Electrical Insulation, 2005, 12 (5): 1015-1024.
  • 4Graiver D, Farminer K W, Narayan R. A review of the fate andeffects of silicones in the environment [J]. Journal of Polymers andthe Environment, 2003, 11 (4): 129-136.
  • 5Mitra S, Ghanbari-siahkali A, Kingshott P, Kristoffer A, RehmeierH K, Christensen A G. Chemical degradation of an uncrosslinked purefluororubber in an alkaline environment [J]. Journal of PolymerScience Part A: Polymer Chemistry, 2004, 83: 195-206.
  • 6Mitra S, Ghanbari-siahkali A, Kingshott P, Pehmeier H K,Abildgaard H, Kristoffer A. Chemical degradation of crosslinkedethylene-propylene-diene rubber in an acidic environment (Ⅰ): Effecton accelerated sulphur crosslinks [J]. Polymer Degradation andStability, 2006, 91 (1): 69-80.
  • 7Mitra S, Ghanbari-siahkali A, Kingshott P, Pehmeier H K,Abildgaard H, Kristoffer A. Chemical degradation of crosslinkedethylene-propylene-diene rubber in an acidic environment (Ⅱ): Effectof peroxide crosslinking in the presence of a coagent [J]. PolymerDegradation and Stability, 2006, 91 (1): 81-93.
  • 8Lin C W, Chien C H, Tan J, Chao Y J, van Zee J W. Chemicaldegradation of five elastomeric seal materials in a simulated and anaccelerated PEM fuel cell environment [J]. Journal of Power Sources,2011, 196 (4): 1955-1966.
  • 9Tan J, Chao Y J, Wang H, Gong J M, van Zee J W. Chemical andmechanical stability of EPDM in a PEM fuel cell environment [J].Polym. Degrad. Stab., 2009, 94 (11): 2072-2078.
  • 10Tan J, Chao Y J, van Zee J W, Li X, Wang X, Yang M. Assessment ofmechanical properties of fluoroelastomer and EPDM in a simulatedPEM fuel cell environment by microindentation test [J]. Mater. Sci.Eng. A., 2008, 496: 464-470.

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化工学报
2008年 第8期

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