Effects of assembling method and force on the performance of proton‐exchange membrane fuel cells with metal foam flow field

Summary Recently, highly porous metal foams have been used to replace the traditional open‐flow channels to improve gas transport and distribution in the cells. Deformation of flow plate, gas diffusion layer (GDL), and metal foam may occur during assembling. When the cell size is small, the deformat...

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Veröffentlicht in:	International journal of energy research 2020-10, Vol.44 (12), p.9707-9713
Hauptverfasser:	Weng, Li‐Fang, Jhuang, Jhe‐Wei, Bhavanari, Mallikarjun, Lee, Kan‐Rong, Lai, Yu‐Hsien, Tseng, Chung‐Jen
Format:	Artikel
Sprache:	eng
Schlagworte:	Analytical methods assembling Cell size Clamping Compression compression force Contact pressure Deformation Deformation effects Diffusion layers Diffusion plating Distribution Electrochemical impedance spectroscopy Electrochemistry Energy & Fuels Flow channels Flow distribution flow field Foamed metals Foams Force distribution Fuel cells Fuel technology Gas transport Gaseous diffusion Mass transfer metal foam Metal foams Metals Nuclear Science & Technology Pressure Proton exchange membrane fuel cells proton‐exchange membrane fuel cell Resistance factors Scanning electron microscopy Science & Technology Spectroscopy Stress concentration Technology Uniform flow
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container_title	International journal of energy research
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creator	Weng, Li‐Fang Jhuang, Jhe‐Wei Bhavanari, Mallikarjun Lee, Kan‐Rong Lai, Yu‐Hsien Tseng, Chung‐Jen
description	Summary Recently, highly porous metal foams have been used to replace the traditional open‐flow channels to improve gas transport and distribution in the cells. Deformation of flow plate, gas diffusion layer (GDL), and metal foam may occur during assembling. When the cell size is small, the deformation may not be significant. For large area cells, the deformation may become significant to affect the cell performance. In this study, an assembling device that is capable of applying uniform clamping force is built to facilitate fuel cell assembling and alleviate the deformation. A compressing plate that is the same size of the active area is used to apply uniform clamping force before surrounding bolts are fastened. Therefore, bending of the flow plate and deformation of GDL and metal foam can be minimized. Effects of the clamping force on the microstructures of GDL and metal foam, various resistances, pressure drops, and cell performance are investigated. Distribution of the contact pressure between metal foam and GDL is measured by using pressure sensitive films. Field‐emission scanning electron microscope is used to observe the microstructures. Electrochemical impedance spectroscopy analysis is used measure resistances. The fuel cell performance is measured by using a fuel cell test system. For the cell design used in this study, the optimum clamping force is found to be 200 kgf. Using this optimum clamping force, the cell performance can be enhanced by 50%, as compared with that of the cell assembled without using clamping plates. With appropriate clamping force, the compression force distribution across the entire cell area can approach uniform. This enables uniform flow distribution and reduces mass transfer resistance. Good contact between GDL and metal foam also lowers the interface resistance. All these factors contribute to the enhanced cell performance. An assembling device capable of applying uniform clamping force is built to facilitate fuel cell assembling and maintain the flow field uniformity. With the optimum clamping force of 200 kgf, the cell performance is enhanced by 50%, due to reduced mass transfer resistance and interface resistance provided by the resultant uniform compression pressure distribution.
doi_str_mv	10.1002/er.5611
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Deformation of flow plate, gas diffusion layer (GDL), and metal foam may occur during assembling. When the cell size is small, the deformation may not be significant. For large area cells, the deformation may become significant to affect the cell performance. In this study, an assembling device that is capable of applying uniform clamping force is built to facilitate fuel cell assembling and alleviate the deformation. A compressing plate that is the same size of the active area is used to apply uniform clamping force before surrounding bolts are fastened. Therefore, bending of the flow plate and deformation of GDL and metal foam can be minimized. Effects of the clamping force on the microstructures of GDL and metal foam, various resistances, pressure drops, and cell performance are investigated. Distribution of the contact pressure between metal foam and GDL is measured by using pressure sensitive films. Field‐emission scanning electron microscope is used to observe the microstructures. Electrochemical impedance spectroscopy analysis is used measure resistances. The fuel cell performance is measured by using a fuel cell test system. For the cell design used in this study, the optimum clamping force is found to be 200 kgf. Using this optimum clamping force, the cell performance can be enhanced by 50%, as compared with that of the cell assembled without using clamping plates. With appropriate clamping force, the compression force distribution across the entire cell area can approach uniform. This enables uniform flow distribution and reduces mass transfer resistance. Good contact between GDL and metal foam also lowers the interface resistance. All these factors contribute to the enhanced cell performance. An assembling device capable of applying uniform clamping force is built to facilitate fuel cell assembling and maintain the flow field uniformity. 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Deformation of flow plate, gas diffusion layer (GDL), and metal foam may occur during assembling. When the cell size is small, the deformation may not be significant. For large area cells, the deformation may become significant to affect the cell performance. In this study, an assembling device that is capable of applying uniform clamping force is built to facilitate fuel cell assembling and alleviate the deformation. A compressing plate that is the same size of the active area is used to apply uniform clamping force before surrounding bolts are fastened. Therefore, bending of the flow plate and deformation of GDL and metal foam can be minimized. Effects of the clamping force on the microstructures of GDL and metal foam, various resistances, pressure drops, and cell performance are investigated. Distribution of the contact pressure between metal foam and GDL is measured by using pressure sensitive films. Field‐emission scanning electron microscope is used to observe the microstructures. Electrochemical impedance spectroscopy analysis is used measure resistances. The fuel cell performance is measured by using a fuel cell test system. For the cell design used in this study, the optimum clamping force is found to be 200 kgf. Using this optimum clamping force, the cell performance can be enhanced by 50%, as compared with that of the cell assembled without using clamping plates. With appropriate clamping force, the compression force distribution across the entire cell area can approach uniform. This enables uniform flow distribution and reduces mass transfer resistance. Good contact between GDL and metal foam also lowers the interface resistance. All these factors contribute to the enhanced cell performance. An assembling device capable of applying uniform clamping force is built to facilitate fuel cell assembling and maintain the flow field uniformity. With the optimum clamping force of 200 kgf, the cell performance is enhanced by 50%, due to reduced mass transfer resistance and interface resistance provided by the resultant uniform compression pressure distribution.</description><subject>Analytical methods</subject><subject>assembling</subject><subject>Cell size</subject><subject>Clamping</subject><subject>Compression</subject><subject>compression force</subject><subject>Contact pressure</subject><subject>Deformation</subject><subject>Deformation effects</subject><subject>Diffusion layers</subject><subject>Diffusion plating</subject><subject>Distribution</subject><subject>Electrochemical impedance spectroscopy</subject><subject>Electrochemistry</subject><subject>Energy & Fuels</subject><subject>Flow channels</subject><subject>Flow distribution</subject><subject>flow field</subject><subject>Foamed metals</subject><subject>Foams</subject><subject>Force distribution</subject><subject>Fuel cells</subject><subject>Fuel technology</subject><subject>Gas transport</subject><subject>Gaseous diffusion</subject><subject>Mass transfer</subject><subject>metal foam</subject><subject>Metal foams</subject><subject>Metals</subject><subject>Nuclear Science & Technology</subject><subject>Pressure</subject><subject>Proton exchange membrane fuel cells</subject><subject>proton‐exchange membrane fuel cell</subject><subject>Resistance factors</subject><subject>Scanning electron microscopy</subject><subject>Science & Technology</subject><subject>Spectroscopy</subject><subject>Stress concentration</subject><subject>Technology</subject><subject>Uniform flow</subject><issn>0363-907X</issn><issn>1099-114X</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2020</creationdate><recordtype>article</recordtype><sourceid>AOWDO</sourceid><recordid>eNqNkM1KAzEUhYMoWH_wFQIuXMjUZCadZJZS6g8IgrhwN2QyN-2UTFKTlNqF4CP4jD6JqRVxI7jKTe53Tg4HoRNKhpSQ_AL8cFRSuoMGlFRVRil72kUDUpRFVhH-tI8OQpgTknaUD9DrRGtQMWCnsQwB-sZ0dop7iDPXYmlbrJ1XgJ3FcQZ4AT7de2k3TxovvIvOfry9w4uaSTuFJOwbLy1gvQSDFRgT8KqLs42jNMlM9lgbt8K6A9MeoT0tTYDj7_MQPV5NHsc32d399e348i5TRZ7TrFQFNLyVwDQjIgWmbSVGVAjJSxCCl4JJznKSq1LypiEUWEG0EFoy3ZZNcYhOt7Yp7_MSQqznbult-rHOGSu4ILysEnW2pZR3IXjQ9cJ3vfTrmpJ6U20Nvt5Um0ixJVfQOB1UB6mPHzp1O2K5YDRPE6HjLsrYOTt2SxuT9Pz_0l90Z2D9V5568vAV6xNny5xP</recordid><startdate>20201010</startdate><enddate>20201010</enddate><creator>Weng, Li‐Fang</creator><creator>Jhuang, Jhe‐Wei</creator><creator>Bhavanari, Mallikarjun</creator><creator>Lee, Kan‐Rong</creator><creator>Lai, Yu‐Hsien</creator><creator>Tseng, Chung‐Jen</creator><general>John Wiley & Sons, Inc</general><general>Wiley</general><general>Hindawi Limited</general><scope>AOWDO</scope><scope>BLEPL</scope><scope>DTL</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7SP</scope><scope>7ST</scope><scope>7TB</scope><scope>7TN</scope><scope>8FD</scope><scope>C1K</scope><scope>F1W</scope><scope>F28</scope><scope>FR3</scope><scope>H96</scope><scope>KR7</scope><scope>L.G</scope><scope>L7M</scope><scope>SOI</scope><orcidid>https://orcid.org/0000-0002-7831-411X</orcidid><orcidid>https://orcid.org/0000-0003-1365-5789</orcidid></search><sort><creationdate>20201010</creationdate><title>Effects of assembling method and force on the performance of proton‐exchange membrane fuel cells with metal foam flow field</title><author>Weng, Li‐Fang ; 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Deformation of flow plate, gas diffusion layer (GDL), and metal foam may occur during assembling. When the cell size is small, the deformation may not be significant. For large area cells, the deformation may become significant to affect the cell performance. In this study, an assembling device that is capable of applying uniform clamping force is built to facilitate fuel cell assembling and alleviate the deformation. A compressing plate that is the same size of the active area is used to apply uniform clamping force before surrounding bolts are fastened. Therefore, bending of the flow plate and deformation of GDL and metal foam can be minimized. Effects of the clamping force on the microstructures of GDL and metal foam, various resistances, pressure drops, and cell performance are investigated. Distribution of the contact pressure between metal foam and GDL is measured by using pressure sensitive films. Field‐emission scanning electron microscope is used to observe the microstructures. Electrochemical impedance spectroscopy analysis is used measure resistances. The fuel cell performance is measured by using a fuel cell test system. For the cell design used in this study, the optimum clamping force is found to be 200 kgf. Using this optimum clamping force, the cell performance can be enhanced by 50%, as compared with that of the cell assembled without using clamping plates. With appropriate clamping force, the compression force distribution across the entire cell area can approach uniform. This enables uniform flow distribution and reduces mass transfer resistance. Good contact between GDL and metal foam also lowers the interface resistance. All these factors contribute to the enhanced cell performance. An assembling device capable of applying uniform clamping force is built to facilitate fuel cell assembling and maintain the flow field uniformity. With the optimum clamping force of 200 kgf, the cell performance is enhanced by 50%, due to reduced mass transfer resistance and interface resistance provided by the resultant uniform compression pressure distribution.</abstract><cop>Chichester, UK</cop><pub>John Wiley & Sons, Inc</pub><doi>10.1002/er.5611</doi><tpages>7</tpages><orcidid>https://orcid.org/0000-0002-7831-411X</orcidid><orcidid>https://orcid.org/0000-0003-1365-5789</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Analytical methods assembling Cell size Clamping Compression compression force Contact pressure Deformation Deformation effects Diffusion layers Diffusion plating Distribution Electrochemical impedance spectroscopy Electrochemistry Energy & Fuels Flow channels Flow distribution flow field Foamed metals Foams Force distribution Fuel cells Fuel technology Gas transport Gaseous diffusion Mass transfer metal foam Metal foams Metals Nuclear Science & Technology Pressure Proton exchange membrane fuel cells proton‐exchange membrane fuel cell Resistance factors Scanning electron microscopy Science & Technology Spectroscopy Stress concentration Technology Uniform flow
title	Effects of assembling method and force on the performance of proton‐exchange membrane fuel cells with metal foam flow field
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