A Metric for Characterization of Multifunctional Fuel Cell Designs
作者: Corydon D. Hilton , Daniel M. Peairs , John J. Lesko , Scott W. Case
DOI: 10.1115/1.4003760
关键词: Control engineering 、 Materials science 、 Automotive engineering 、 Stiffness 、 Characterization (materials science) 、 Metric (mathematics) 、 Fuel cells 、 Mechanical engineering 、 Renewable Energy, Sustainability and the Environment 、 Mechanics of Materials 、 Energy Engineering and Power Technology 、 Electronic, Optical and Magnetic Materials
摘要: The U.S. Army has investigated a variety of multifunctional designs in order to achieve system level mass and/or volume savings. One of the multifunctional devices developed is the multifunctional fuel cell (MFC)—a fuel cell which simultaneously provides a system with structural support and power generation. However, there are no established methods for measuring how well a particular design performs or its multifunctional advantage. The current paper presents a metric by which multifunctional fuel cell designs can be characterized. The mechanical aspect of the metric is based on the specific bending stiffness of the structural cell and is developed using Frostig’s high-order theory. The electrical component of the metric is based on the specific power density achieved by the structural cell. The structural systems considered here display multifunctional efficiencies ranging from 22% to 69%. The higher efficiency was obtained by optimizing the contact pressure at the gas diffusion layer (GDL) in a model cell design. The efficiencies obtained suggest the need for improved multifunctional designs in order to reach system level mass savings.
asme.org
sci-hub.se 参考文章(20)
B. K. Kakati, V. Mohan, Development of Low‐Cost Advanced Composite Bipolar Plate for Proton Exchange Membrane Fuel Cell Fuel Cells. ,vol. 8, pp. 45- 51 ,(2008) , 10.1002/FUCE.200700008
Stephen R. Swanson, An examination of a higher order theory for sandwich beams Composite Structures. ,vol. 44, pp. 169- 177 ,(1999) , 10.1016/S0263-8223(98)00130-5
Jin Dai, H. Thomas Hahn, Flexural behavior of sandwich beams fabricated by vacuum-assisted resin transfer molding Composite Structures. ,vol. 61, pp. 247- 253 ,(2003) , 10.1016/S0263-8223(03)00040-0
James Guerrero, Eugene R. Fosness, Ken Qassim, Overview of Multifunctional Structure Efforts at the Air Force Research Laboratory Scientific Programming. pp. 319- 326 ,(2000) , 10.1061/40479(204)37
Y. Shenhar, Y. Frostig, E. Altus, Stresses and failure patterns in the bending of sandwich beams with transversely flexible cores and laminated composite skins Composite Structures. ,vol. 35, pp. 143- 152 ,(1996) , 10.1016/0263-8223(96)00016-5
James F. Snyder, Robert H. Carter, Eric D. Wetzel, Electrochemical and mechanical behavior in mechanically robust solid polymer electrolytes for use in multifunctional structural batteries Chemistry of Materials. ,vol. 19, pp. 3793- 3801 ,(2007) , 10.1021/CM070213O
Y. Frostig, M. Baruch, O. Vilnay, I. Sheinman, High‐Order Theory for Sandwich‐Beam Behavior with Transversely Flexible Core Journal of Engineering Mechanics. ,vol. 118, pp. 1026- 1043 ,(1992) , 10.1061/(ASCE)0733-9399(1992)118:5(1026)
V. Sokolinsky, Y. Frostig, Nonlinear Behavior of Sandwich Panels with a Transversely Flexible Core AIAA Journal. ,vol. 37, pp. 1474- 1482 ,(1999) , 10.2514/2.625
Stephen R. Swanson, Jongman Kim, Comparison of a Higher Order Theory for Sandwich Beams with Finite Element and Elasticity Analyses Journal of Sandwich Structures and Materials. ,vol. 2, pp. 33- 49 ,(2000) , 10.1177/109963620000200102
Y. Frostig, Y. Shenhar, High-order bending of sandwich beams with a transversely flexible core and unsymmetrical laminated composite skins Composites Engineering. ,vol. 5, pp. 405- 414 ,(1995) , 10.1016/0961-9526(95)93440-7