Long term performance degradation analysis and optimization of anode supported solid oxide fuel cell stacks

Abstract The main objective of this work is minimizing the cost of electricity of solid oxide fuel cell stacks by decelerating degradation mechanisms rate in long term operation for stationary power generation applications. The degradation mechanisms in solid oxide fuel cells are caused by microstructural changes, reactions between lanthanum strontium manganite and electrolyte, poisoning by chromium, carburization on nickel particles, formation of nickel sulfide, nickel coarsening, nickel oxidation, loss of conductivity and crack formation in the electrolyte. The rate of degradation mechanisms depends on the cell operating conditions (cell voltage and fuel utilization). In this study, the degradation based optimization framework is developed which determines optimum operating conditions to achieve a minimum cost of electricity. To show the effectiveness of the developed framework, optimization results are compared with the case that system operates at its design point. Results illustrate optimum operating conditions decrease the cost of electricity by 7.12%. The performed study indicates that degradation based optimization is a beneficial concept for long term performance degradation analysis of energy conversion systems.

[1]  Osama A. Mohammed,et al.  An advanced real time energy management system for microgrids , 2016 .

[2]  Thinh X. Ho,et al.  Dynamic characteristics of a solid oxide fuel cell with direct internal reforming of methane , 2016 .

[3]  Ellen Ivers-Tiffée,et al.  INFLUENCE OF CURRENT DENSITY AND FUEL UTILIZATION ON THE DEGRADATION OF THE ANODE , 1998 .

[4]  H. Saunders,et al.  Probabilistic models of cumulative damage , 1985 .

[5]  Pedro Nehter,et al.  A high fuel utilizing solid oxide fuel cell cycle with regard to the formation of nickel oxide and power density , 2007 .

[6]  Daniel Favrat,et al.  Progressive activation of degradation processes in solid oxide fuel cell stacks: Part II: Spatial distribution of the degradation , 2012 .

[7]  D. Favrat,et al.  Mechanical reliability and durability of SOFC stacks. Part I: Modelling of the effect of operating conditions and design alternatives on the reliability , 2012 .

[8]  Marco Cannarozzo,et al.  Experimental and Theoretical Investigation of Degradation Mechanisms by Particle Coarsening in SOFC Electrodes , 2009 .

[9]  Dario Marra,et al.  Development of solid oxide fuel cell stack models for monitoring, diagnosis and control applications , 2013 .

[10]  Linda Barelli,et al.  SOFC direct fuelling with high-methane gases: Optimal strategies for fuel dilution and upgrade to avoid quick degradation , 2016 .

[11]  Greg A. Whyatt,et al.  Cost Study for Manufacturing of Solid Oxide Fuel Cell Power Systems , 2013 .

[12]  H. Joseph Wen,et al.  Single solid oxide fuel cell modeling and optimization , 2011 .

[13]  L. Kiwi-Minsker,et al.  Mathematical modelling of the unsteady-state oxidation of nickel gauze catalysts , 2003 .

[14]  D. Favrat,et al.  Progressive activation of degradation processes in solid oxide fuel cells stacks: Part I: Lifetime extension by optimisation of the operating conditions , 2012 .

[15]  Lin Liu Solid oxide fuel cell reliability and performance modeling and fabrication by spray pyrolysis , 2011 .

[16]  Robert J. Braun,et al.  Techno-economic analysis of solid oxide fuel cell-based combined heat and power systems for biogas utilization at wastewater treatment facilities , 2013 .

[17]  Ramin Roshandel,et al.  Degradation based optimization framework for long term applications of energy systems, case study: Solid oxide fuel cell stacks , 2016 .

[18]  M. P. Moghaddam,et al.  Optimised performance of a plug-in electric vehicle aggregator in energy and reserve markets , 2015 .

[19]  Zhe Cheng,et al.  A solid oxide fuel cell operating on hydrogen sulfide (H2S) and sulfur-containing fuels , 2004 .

[20]  E. Thomsen,et al.  Degradation mechanisms of SOFC anodes in coal gas containing phosphorus , 2010 .

[21]  J. Neidhardt,et al.  Nickel oxidation in solid oxide cells : modeling and simulation of multi-phase electrochemistry and multi-scale transport , 2013 .

[22]  Adriano V. Ensinas,et al.  Thermo-economic optimization of a Solid Oxide Fuel Cell – Gas turbine system fuelled with gasified lignocellulosic biomass , 2014 .

[23]  O. Joneydi Shariatzadeh,et al.  Economic optimisation and thermodynamic modelling of SOFC tri-generation system fed by biogas , 2015 .

[24]  Wei Wang,et al.  Electrochemical Analysis of an Anode-Supported SOFC , 2013, International Journal of Electrochemical Science.

[25]  J. Van herle,et al.  Nickel–Zirconia Anode Degradation and Triple Phase Boundary Quantification from Microstructural Analysis , 2009 .

[26]  P. D. T. O'Connor Probabilistic models of cumulative damage, J. L. BOGDANOFF and F. KOZIN, Wiley-Interscience, New York 1985, No. of pages: 352, Price £67.75; $71.15 , 1985 .

[27]  John B. Goodenough,et al.  Solid Oxide Fuel Cell Technology: Principles, Performance and Operations , 2009 .

[28]  L. Barelli,et al.  SOFC regulation at constant temperature: Experimental test and data regression study , 2016 .