Rate‐Determining Step Investigations of Oxidation Processes at the Positive Plate during Pulse Charge of Valve‐Regulated Lead‐Acid Batteries

Today, it is possible to design a mathematical model of lead-acid battery on a laptop from scratch with MATLAB. It still takes time to develop, but nowadays these models alone cannot be considered innovations anymore because anybody is able to do the same with the appropriate tools. More than ever, the actual innovation lies in the answer given to the most important question: a model to do what? Here, the model’s main goal is to simulate the flooded battery behavior in all vehicle life cycles. Thus, it seems legitimate to validate them under different operating conditions with experimental data to prove that the simulation results are reliable. It is challenging but feasible, notably by making a correct selection of the parameter value ranges and studying how they influence the output. Another goal is to understand the battery behavior changes due to the physicochemical processes involved at various rates and temperatures to explain Peukert’s law and the impact of temperature on vehicle cranking. The final objective of this model is to find parameter changes corresponding to the main aging phenomena to simulate new and also used batteries.

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confidence: 99%

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confidence: 99%

A Mathematical Model for the Simulation of New and Aged Automotive Lead-Acid Batteries

Cugnet

Laruelle

Grugeon

et al. 2009

“…It should be noted that there are reports in the literature of considerable higher exchange current densities for the reaction. For example, LaFollette and Bennion 28 use a value of 1.78 mA/cm 2 , while Guo et al 29 and Carr and Hampson 30 use 0.32 mA/cm 2 , all three authors suggesting that the electrode reaction is facile. The latter value appears to have originated from a paper by Aguf, 31 where the exchange current density of this reaction was measured using impedance spectroscopy.…”

Section: ͓20͔mentioning

confidence: 99%

Mathematical Modeling of Current-Interrupt and Pulse Operation of Valve-Regulated Lead Acid Cells

Srinivasan

Wang

2003

Electric and hybrid electric vehicles use valve-regulated lead acid ͑VRLA͒ cells that are subjected to dynamic operation with charge, rest, and discharge periods in the order of seconds. Such operation requires more sophisticated models that incorporate the electrochemical double layer. While this effect has been incorporated in a handful of electrochemical systems, the lead-acid cell, with its sluggish reaction kinetics, is one of the few where it is significant. This significance is demonstrated with use of the current-interrupt technique, where the model is used to provide guidelines for the estimation of various resistances. The usefulness of the modeling approach is exemplified by its ability to explore the effect of changing electrochemical area and concentration with state of charge, and the role of parasitic side reactions in the voltage response of the cell. Simulations of pulse charging and dynamic stress test of VRLA cells, where considerable differences are shown when including the double layer, illustrate the need for modifying the presently used modeling approach. In addition, simulations are compared to current-interrupt experiments on commercial cells in order to evaluate the applicability of the model and to identify the differences.With renewed interest in the development of electric and hybrid electric vehicles over the last decade, advanced batteries have received much attention. At present, only the valve-regulated lead acid ͑VRLA͒ and the nickel-metal hydride ͑Ni-MH͒ battery are being actively considered for these applications, while Li-ion cells could become more popular in the future when all safety-related issues are resolved. Of the two candidate battery systems, the low cost and ease of operation of the VRLA battery assures it a prominent role in the years to come. This can be seen from the choice of the VRLA battery as the main power source in a number of electric vehicles ͑EVs͒ and as a high power source used in conjunction with an internal combustion engine in hybrid electric vehicles ͑HEVs͒.This renewed interest has spurred research in this area, with focus on improving the performance of the system and tailoring the manufacturing process to achieve the requisite power and energy demands. In particular, the ability of the battery to handle the simplified federal urban driving schedule ͑SFUDS͒ and the dynamic stress test ͑DST͒ 1 are being extensively studied, as they provide a suitable yardstick to characterize the performance of EV batteries. These schedules, which involve repeated discharge, rest, and charge periods, each lasting a few seconds, test the dynamic response of the system. In addition, recent evidence that the cycle life of the VRLA battery can be extended considerably by the use of smart charging algorithms 2 has spurred interest in current interrupt ͑CI͒, 3 pulse, and ''burp'' ͑i.e., where a short discharge pulse is incorporated during a pulse charge process͒ charging of the battery. 4 While considerable effort has gone into testing batteries under these schemes, a co...

“…The pulsedcurrent charge not only shortens the charge time but also overcomes PCL 2 and hence prolongs the cycle life of the batteries. [9][10][11][12] In an optimized design, the ratio of the active mass between the positive and negative plates is important to the battery life. 13,14 As the utilization of PAM is much lower than that of the negative active mass, great attention has been paid to the investigations on PAM utilization in the past decades.…”

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confidence: 99%

Investigation of Active Mass Utilization of Positive Plate in Automotive Lead-Acid Batteries

Guo

2005

Self Cite

The active mass ͑AM͒ utilization is a key factor limiting the specific energy and performance of lead-acid batteries. In this paper, the distributions of AM utilization on two kinds of positive plates have been studied by measuring their local discharge curves. With the discharge of the positive plate, the current density decreases gradually in the lower and upper parts while it increases in the middle. As a result, the distributions of AM utilization are uneven on the positive plate. The highest AM utilization is located in the middle, and the lowest AM utilization is around the plate. Compared with a positive plate with an orthogonal grid, the positive electrode potential increases by 10-50 mV in most parts of a positive plate with a radiation grid at high discharge rate ͑3C͒. The positive plate with a radiation grid is more suitable for the application at high discharge rates.