Influence of H2SO4 concentration on lead-acid battery performance

“…During the discharge, this can be formation of Pb(OH) 2 and orthorhombic-PbO, which cannot be converted to PbSO 4 . Also recent studies showed that when the electrolyte density is higher than or equal to 1.28 s.g., the discharge capacity decreases compared to s.g. 1.24 g ml −1 , where the capacity is maximal [56]. The morphology of the lead dioxide and the ␣/␤ ratio also changes dramatically from electrolytes with s.g. 1.24-1.28 g ml −1 : the deposits, obtained in electrolyte with s.g. 1.28 g ml −1 by Planté cycling, present much less surface and much more ␣-PbO 2 and tetragonal-PbO, compared with deposits obtained in electrolytes with s.g. 1.24 g ml −1 : where the obtained anodic layers are thicker, with developed surface and built mainly by ␤-PbO 2 [53][54][55].…”

“…This result coincides with some recently reported results about the electrochemical activity of the lead dioxide in electrolytes with different concentrations. Both the studies on flat model electrodes and on pasted positive plates show that electrolyte density equal to 1.28 s.g. or higher causes loss of electrochemical activity of the lead dioxide [53][54][55] as well as decreased discharge capacity and shorter cycle life of the positive plate [56].…”

Studies of the pulse charge of lead-acid batteries for PV applications

“…During the discharge, this can be formation of Pb(OH) 2 and orthorhombic-PbO, which cannot be converted to PbSO 4 . Also recent studies showed that when the electrolyte density is higher than or equal to 1.28 s.g., the discharge capacity decreases compared to s.g. 1.24 g ml −1 , where the capacity is maximal [56]. The morphology of the lead dioxide and the ␣/␤ ratio also changes dramatically from electrolytes with s.g. 1.24-1.28 g ml −1 : the deposits, obtained in electrolyte with s.g. 1.28 g ml −1 by Planté cycling, present much less surface and much more ␣-PbO 2 and tetragonal-PbO, compared with deposits obtained in electrolytes with s.g. 1.24 g ml −1 : where the obtained anodic layers are thicker, with developed surface and built mainly by ␤-PbO 2 [53][54][55].…”

“…This result coincides with some recently reported results about the electrochemical activity of the lead dioxide in electrolytes with different concentrations. Both the studies on flat model electrodes and on pasted positive plates show that electrolyte density equal to 1.28 s.g. or higher causes loss of electrochemical activity of the lead dioxide [53][54][55] as well as decreased discharge capacity and shorter cycle life of the positive plate [56].…”

Studies of the pulse charge of lead-acid batteries for PV applications

“…Hence, to ensure sufficient “sacrificial” water, mass convection, and avoid electrolyte stratification during operation, the concentrated acid electrolyte must be reasonably diluted from saturation. In fact, converse to commercial LIB systems, higher power rate cycling and less concentrated electrolytes both directly contribute to longer cycle lives of lead–acid batteries …”

Water in Rechargeable Multivalent‐Ion Batteries: An Electrochemical Pandora's Box

“…The anodic and cathodic peaks obtained between -1.10 -(-0.9) V, represents the formation of lead sulfate from metallic lead and metallic lead from lead sulfate, respectively [21][22][23]. Here, we have investigated the formation of lead sulfate in cyclic voltammetric studies.…”

A Novel Gel Electrolyte for Valve-Regulated Lead Acid Battery