Mitigating capacity decay and improving charge-discharge performance of a vanadium redox flow battery with asymmetric operating conditions

Abstract A two-dimensional transient model with considering vanadium ion crossover was presented to examine the influence of asymmetric electrolyte concentrations and operation pressures strategies on the characteristics of capacity decay, vanadium ions crossover and charge-discharge performance of a vanadium redox flow battery during battery cycling. It was indicated that for asymmetric electrolyte operating concentrations, with increasing the initial concentration of positive electrolyte while keeping initial concentration of negative electrolyte unchanged, the discharge capacity decay behavior during battery cycling can be effectively mitigated due to the reason that the imbalance of vanadium ions crossover is alleviated by the increased diffusion flux of VO2+/VO2+ couple from positive to negative side. Also, the overall charge-discharge performance of the battery is greatly improved due to the reduced potential losses of both electrode reactions. Moreover, it was shown that the discharge capacity decay can also be suppressed by increasing the outlet pressure of positive electrode, which is attributed to the reason that the imbalance of vanadium ions crossover can be eliminated with the increased vanadium osmotic convection driven by pressure gradient. However, asymmetric operation pressures showed little impact on batter charge-discharge voltages.

[1]  Arvind R. Kalidindi,et al.  A Transient Vanadium Flow Battery Model Incorporating Vanadium Crossover and Water Transport through the Membrane , 2012 .

[2]  G. Graff,et al.  A Stable Vanadium Redox‐Flow Battery with High Energy Density for Large‐Scale Energy Storage , 2011 .

[3]  Maria Skyllas-Kazacos,et al.  Vanadium Electrolyte Studies for the Vanadium Redox Battery-A Review. , 2016, ChemSusChem.

[4]  A. Bischi,et al.  Zero dimensional dynamic model of vanadium redox flow battery cell incorporating all modes of vanadium ions crossover , 2018, Applied Energy.

[5]  Mohd Herwan Sulaiman,et al.  Performance characterization of a vanadium redox flow battery at different operating parameters under a standardized test-bed system , 2015 .

[6]  Qiang Ye,et al.  Effects of the electric field on ion crossover in vanadium redox flow batteries , 2015 .

[7]  Changwei Hu,et al.  Coulter dispersant as positive electrolyte additive for the vanadium redox flow battery , 2012 .

[8]  Matthew M. Mench,et al.  Influence of architecture and material properties on vanadium redox flow battery performance , 2016 .

[9]  C. R. Dennison,et al.  Reducing capacity fade in vanadium redox flow batteries by altering charging and discharging currents , 2014 .

[10]  W. Xing,et al.  Balancing Osmotic Pressure of Electrolytes for Nanoporous Membrane Vanadium Redox Flow Battery with a Draw Solute. , 2016, ACS applied materials & interfaces.

[11]  J. Košek,et al.  Commercial perfluorosulfonic acid membranes for vanadium redox flow battery: Effect of ion-exchange capacity and membrane internal structure , 2018 .

[12]  Qiuwan Wang,et al.  Experimental study on the performance of a vanadium redox flow battery with non-uniformly compressed carbon felt electrode , 2018 .

[13]  Frank C. Walsh,et al.  A dynamic performance model for redox-flow batteries involving soluble species , 2008 .

[14]  B. Li,et al.  Capacity decay mechanism of microporous separator-based all-vanadium redox flow batteries and its recovery. , 2014, ChemSusChem.

[15]  H. Ju,et al.  Numerical analysis of vanadium crossover effects in all-vanadium redox flow batteries , 2015 .

[16]  T. Zhao,et al.  Performance of a vanadium redox flow battery with and without flow fields , 2014 .

[17]  Uwe Schröder,et al.  On-line controlled state of charge rebalancing in vanadium redox flow battery , 2013 .

[18]  J. Park,et al.  Capacity Decay Mitigation by Asymmetric Positive/Negative Electrolyte Volumes in Vanadium Redox Flow Batteries. , 2016, ChemSusChem.

[19]  Zhiguo Qu,et al.  Numerical study on vanadium redox flow battery performance with non-uniformly compressed electrode and serpentine flow field , 2018, Applied Energy.

[20]  Jingyu Xi,et al.  Asymmetric vanadium flow batteries: long lifespan via an anolyte overhang strategy. , 2017, Physical chemistry chemical physics : PCCP.

[21]  Young-Seak Lee,et al.  Effect of inorganic additive sodium pyrophosphate tetrabasic on positive electrolytes for a vanadium redox flow battery , 2014 .

[22]  Emin Caglan Kumbur,et al.  Role of convection and related effects on species crossover and capacity loss in vanadium redox flow batteries , 2012 .

[23]  Weiwei Yang,et al.  Performance Modeling of a Vanadium Redox Flow Battery during Discharging , 2015 .

[24]  Zhenguo Yang,et al.  Cycling performance and efficiency of sulfonated poly(sulfone) membranes in vanadium redox flow batteries , 2010 .

[25]  Maria Skyllas-Kazacos,et al.  Modeling of vanadium ion diffusion across the ion exchange membrane in the vanadium redox battery , 2012 .

[26]  S. Jayanti,et al.  Effect of flow field on the performance of an all-vanadium redox flow battery , 2016 .

[27]  Wei Wang,et al.  In-situ investigation of vanadium ion transport in redox flow battery , 2012 .

[28]  C. Dennison,et al.  Enhancing Mass Transport in Redox Flow Batteries by Tailoring Flow Field and Electrode Design , 2016 .

[29]  Xuelong Zhou,et al.  Critical transport issues for improving the performance of aqueous redox flow batteries , 2017 .

[30]  Guiling Ning,et al.  A three-dimensional model for thermal analysis in a vanadium flow battery , 2014 .

[31]  Chenxi Sun,et al.  Investigations on transfer of water and vanadium ions across Nafion membrane in an operating vanadium redox flow battery , 2010 .

[32]  K. Pinkwart,et al.  Detection of capacity imbalance in vanadium electrolyte and its electrochemical regeneration for all-vanadium redox-flow batteries , 2016 .

[33]  Dongjiang You,et al.  A simple model for the vanadium redox battery , 2009 .

[34]  Jie Bao,et al.  Dynamic modelling of the effects of ion diffusion and side reactions on the capacity loss for vanadi , 2011 .

[35]  L. Gubler,et al.  Amphoteric Ion-Exchange Membranes with Significantly Improved Vanadium Barrier Properties for All-Vanadium Redox Flow Batteries. , 2017, ChemSusChem.

[36]  Matthew M. Mench,et al.  Coupled Membrane Transport Parameters for Ionic Species in All-Vanadium Redox Flow Batteries , 2016 .

[37]  Suqin Liu,et al.  Synthesis of boron and nitrogen co-doped carbon nanofiber as efficient metal-free electrocatalyst for the VO2+/VO2+ Redox Reaction , 2015 .

[38]  S. Shanmugam,et al.  Ultra-high proton/vanadium selectivity of a modified sulfonated poly(arylene ether ketone) composite membrane for all vanadium redox flow batteries , 2017 .

[39]  Qian Xu,et al.  Numerical investigations of flow field designs for vanadium redox flow batteries , 2013 .

[40]  M. Mench,et al.  Architecture for improved mass transport and system performance in redox flow batteries , 2017 .

[41]  J. Bao,et al.  Studies on pressure losses and flow rate optimization in vanadium redox flow battery , 2014 .

[42]  Z. Qu,et al.  Effect of various strategies of soc-dependent operating current on performance of a vanadium redox flow battery , 2018 .

[43]  Chenxi Sun,et al.  Simulation of the self-discharge process in vanadium redox flow battery , 2011 .

[44]  Erik Birgersson,et al.  Pulsating electrolyte flow in a full vanadium redox battery , 2015 .

[45]  H. Ju,et al.  A comparative study of species migration and diffusion mechanisms in all-vanadium redox flow batteries , 2015 .

[46]  Emin Caglan Kumbur,et al.  Species transport mechanisms governing capacity loss in vanadium flow batteries: Comparing Nafion® and sulfonated Radel membranes , 2013 .

[47]  Mike L. Perry,et al.  The Influence of Electric Field on Crossover in Redox-Flow Batteries , 2016 .

[48]  Huamin Zhang,et al.  An optimal strategy of electrolyte flow rate for vanadium redox flow battery , 2012 .

[49]  Xinping Qiu,et al.  Reduction of capacity decay in vanadium flow batteries by an electrolyte-reflow method , 2017 .

[50]  Qinghua Liu,et al.  Dramatic performance gains in vanadium redox flow batteries through modified cell architecture , 2012 .

[51]  Hee‐Tak Kim,et al.  A review of vanadium electrolytes for vanadium redox flow batteries , 2017 .

[52]  Xuelong Zhou,et al.  Modeling of ion transport through a porous separator in vanadium redox flow batteries , 2016 .