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Faster Lead-Acid Battery Simulations from Porous-Electrode Theory: I. Physical Model

Authors :
Sulzer, Valentin
Chapman, S. Jon
Please, Colin P.
Howey, David A.
Monroe, Charles W.
Publication Year :
2019

Abstract

An isothermal porous-electrode model of a discharging lead-acid battery is presented, which includes an extension of concentrated-solution theory that accounts for excluded-volume effects, local pressure variation, and a detailed microscopic water balance. The approach accounts for three typically neglected physical phenomena: convection, pressure diffusion, and variation of liquid volume with state of charge. Rescaling of the governing equations uncovers a set of fundamental dimensionless parameters that control the battery's response. Total volume change during discharge and nonuniform pressure prove to be higher-order effects in cells where variations occur in just one spatial dimension. A numerical solution is developed and exploited to predict transient cell voltages and internal concentration profiles in response to a range of C-rates. The dependence of discharge capacity on C-rate deviates substantially from Peukert's simple power law: charge capacity is concentration-limited at low C-rates, and voltage-limited at high C-rates. The model is fit to experimental data, showing good agreement.<br />Comment: Submitted to Journal of the Electrochemical Society. First part of a two-part paper. Part II: "Faster Lead-Acid Battery Simulations from Porous-Electrode Theory: II. Asymptotic Analysis"

Subjects

Subjects :
Physics - Chemical Physics

Details

Database :
arXiv
Publication Type :
Report
Accession number :
edsarx.1902.01771
Document Type :
Working Paper
Full Text :
https://doi.org/10.1149/2.0301910jes