论文信息 - Electroplated reticulated vitreous carbon current collectors for lead–acid batteries: opportunities and challenges

Electroplated reticulated vitreous carbon current collectors for lead–acid batteries: opportunities and challenges

Abstract Reticulated, open-cell structures based on vitreous carbon substrates electroplated with a Pb–Sn (1 wt.%) alloy were investigated as current collectors for lead–acid batteries. Scanning and backscattered electron microscopy, cyclic voltammetry, anodic polarization and flooded 2 V single-cell battery testing was employed to characterize the performance of the proposed collectors. A battery equipped with pasted electroplated reticulated vitreous carbon (RVC) electrodes of 137 cm 2 geometric area, at the time of manuscript submission, completed 500 cycles and over 1500 h of continuous operation. The cycling involved discharges at 63 A kg PAM −1 corresponding to a nominal 0.75 h rate and a positive active mass (PAM) utilization efficiency of 21%. The charging protocol was composed of two voltage limited (i.e. 2.6 V/cell), constant current steps of 35 and 9.5 A kg PAM −1 , respectively, with a total duration of about 2 h. The charge factor was 1.05–1.15. The observed cycling behavior in conjunction with the versatility of electrodeposition to produce application-dependent optimized lead alloy coating thickness and composition shows promise for the development of lead–acid batteries using electroplated reticulated vitreous carbon collectors.

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