Journal of the Chinese Ceramic Society, Volume. 50, Issue 5, 1223(2022)
Residual Thermal Stress and Failure Probability Analysis of Solid Oxide Fuel Cell with Gradient Anode
[1] [1] AKKAYA A V. Electrochemical model for performance analysis of a tubular SOFC[J]. Int J Energy Res, 2007, 31: 79-98.
[2] [2] SUGIHARA K, ASAMOTO M, ITAGAKI Y, et al. A quantitative analysis of influence of Ni particle size of SDC-supported anode on SOFC performance: Effect of particle size of SDC support[J]. Solid State Ionics, 2014, 262: 433-437.
[3] [3] JUNG G B, FANG L H, CHIOU M J, et al. Effects of pretreatment methods on electrodes and SOFC performance[J]. Energies, 2014, 7: 3922-3933.
[4] [4] CEBOLLERO J A, LAHOZ R, LAGUNA-BERCERO M A, et al. Tailoring the electrode-electrolyte interface of solid oxide fuel cells (SOFC) by laser micro-patterning to improve their electrochemical performance[J]. J Power Sources, 2017, 360: 336-344.
[8] [8] XU M, LI T H, YANG M, et al. Solid oxide fuel cell interconnect design optimization considering the thermal stresses[J]. Sci Bull, 2016, 61: 1333-1344.
[9] [9] SELIMOVIC A, KEMM M, TORISSON T, et al. Steady state and transient thermal stress analysis in planar solid oxide fuel cells[J]. J Power Sources, 2005, 145: 463-469.
[10] [10] NAKAJO A, STILLER C, HRKEGRD G, et al. Modeling of thermal stresses and probability of survival of tubular SOFC[J]. J Power Sources, 2006, 158: 287-294.
[11] [11] YAKABE H, BABA Y, SAKURAI T, et al. Evaluation of the residual stress for anode-supported SOFCs[J]. J Power Sources, 2004, 135: 9-16.
[12] [12] ZHANG T, ZHU Q S, HUANG W L, et al. Stress field and failure probability analysis for the single cell of planar solid oxide fuel cells[J]. J Power Sources, 2008, 182: 540-545.
[13] [13] KONG W, ZHANG W X, ZHANG S D, et al. Residual stress analysis of a micro-tubular solid oxide fuel cell[J]. Int J Hydrogen Energy, 2016, 41: 16173-16180.
[14] [14] NI M, LEUNG K H, LEUNG D Y. Micro-scale modelling of solid oxide fuel cells with micro-structurally graded electrodes[J]. J Power Sources, 2007, 168: 369-378.
[15] [15] WANG C, HUANG G, MILLER R. Computational analysis of solid oxide fuel cell with functionally graded electrodes[C]//49th AIAA Aerospace Sciences Meeting including the New Horizons Forum and Aerospace Exposition, 2011.
[16] [16] WANG C. Computational analysis of functionally graded anode in solid oxide fuel cell by involving the correlations of microstructural parameters[J]. Energies, 2016, 9(6): 408.
[17] [17] HU L, WANG C A, HUANG Y, et al. Control of pore channel size during freeze casting of porous YSZ ceramics with unidirectionally aligned channels using different freezing temperatures[J]. J Europ Ceram Soc, 2010, 30: 3389-3396.
[18] [18] MCCOPPIN J, BARNEY I, MUKHOPADHYAY S, et al. Compositional control of continuously graded anode functional layer[J]. J Power Sources, 2012, 215: 160-163.
[19] [19] CHEN Y, ZHANG Y, BAKER J, et al. Hierarchically oriented macroporous anode-supported solid oxide fuel cell with thin ceria electrolyte film[J]. ACS Appl Materi Interfaces, 2014, 6: 5130-6.
[21] [21] WANG Y S, HUANG G Y, GROSS D. On the mechanical modelling of functionally graded interfacial zone with a Griffith crack[J]. Int J Fract, 2004, 70: 676-680.
[22] [22] WANG Y S, HUANG G Y, GROSS D. The fracture analysis of a graded coating/substrate system of finite thickness with arbitrary spatial variations of coating properties: Plane deformation[J]. Eng Fract Mechan, 2005, 72: 1942-1953.
[23] [23] KE L L, WANG Y S. Two-dimensional sliding frictional contact of functionally graded materials[J]. Eur J Mechan A, 2007, 26: 171-188.
[24] [24] KIM K P, BAE K, KIM K H, et al. Reduction of residual thermal stress on anode-supported SOFCs using porous aid layers[J]. Int J Precis Eng Man, 2012, 13: 2149-2154.
[25] [25] ANANDAKUMAR G, LI N, VERMA A, et al. Thermal stress and probability of failure analyses of functionally graded solid oxide fuel cells[J]. J Power Sources, 2010, 195: 6659-6670.
[26] [26] XIE J M, HAO W Q, WANG F H. Analysis of anode functional layer for minimizing thermal stress in solid oxide fuel cell[J]. Appl Phys A, 2017, 123: 1-14.
[27] [27] SAIED M, AHMED K, AHMED M, et al. Investigations of solid oxide fuel cells with functionally graded electrodes for high performance and safe thermal stress[J]. Int J Hydrogen Energy, 2017, 42: 15887-15902.
[28] [28] ATKINSON A, SELCUK A. Residual stress and fracture of laminated ceramic membranes[J]. Acta Mater, 1999, 47: 867-874.
[29] [29] FANG X R, ZHU J, LIN Z J. Effects of electrode composition and thickness on the mechanical performance of a solid oxide fuel cell[J]. Energies, 2018, 11: 1735.
[30] [30] NEMAT-ALLA M. Reduction of thermal stresses by developing two-dimensional functionally graded materials[J]. Int J Solids Struct, 2003, 40: 7339-7356.
[31] [31] MORI M, YAMAMOTO T, ITOH H, et al. Thermal expansion of nickel-zirconia anodes in solid oxide fuel cells during fabrication and operation[J]. J Electrochem Soc, 1998, 145: 1374-1380.
[32] [32] GIRAUD S, CANEL J. Young’s modulus of some SOFCs materials as a function of temperature[J]. J Europ Ceram Soc, 2008, 28: 77-83.
[33] [33] HUBERT O, MILHET X, GADAUD P, et al. Modeling of Young’s modulus variations with temperature of Ni and oxidized Ni using a magneto-mechanical approach[J]. Mater Sci Eng: A, 2015, 633: 76-91.
[34] [34] KIM J W, BAE K, KIM H J, et al. Three-dimensional thermal stress analysis of the re-oxidized Ni-YSZ anode functional layer in solid oxide fuel cells[J]. J Alloys Compds, 2018, 752: 148-154.
[35] [35] NAKAJO A, WUILLEMIN Z, VAN HERLE J, et al. Simulation of thermal stresses in anode-supported solid oxide fuel cell stacks. Part I: Probability of failure of the cells[J]. J Power Sources, 2009, 193: 203-215.
[36] [36] FANG X R, LIN Z J. Numerical study on the mechanical stress and mechanical failure of planar solid oxide fuel cell[J]. Appl Energy, 2018, 229: 63-68.
[37] [37] LI J Y, LIN Z J. Effects of electrode composition on the electrochemical performance and mechanical property of micro-tubular solid oxide fuel cell[J]. Int J Hydrogen Energy, 2012, 37: 12925-12940.
Get Citation
Copy Citation Text
ZHANG Xi, YAN Zilin, ZHOU Yexin, ZHONG Zheng. Residual Thermal Stress and Failure Probability Analysis of Solid Oxide Fuel Cell with Gradient Anode[J]. Journal of the Chinese Ceramic Society, 2022, 50(5): 1223
Category:
Received: May. 10, 2021
Accepted: --
Published Online: Nov. 23, 2022
The Author Email:
CSTR:32186.14.