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

Srinivasan, Venkat; Wang, G. Q.; Wang, C. Y.

doi:10.1149/1.1541005

Cited by 61 publications

(59 citation statements)

References 24 publications

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“…Equation for φ is the same as used the earlier literature, 13,20,21,23 differences coming only through S.…”

Section: Charging-conversion Of Pbmentioning

confidence: 99%

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Modeling of Effect of Double-Layer Capacitance and Failure of Lead-Acid Batteries in HRPSoC Application

Gandhi¹

2017

J. Electrochem. Soc.

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Lead-acid batteries fail faster in partial state-of-charge start-stop technology than in SLI application. Accumulation of lead sulfate on negative electrode's surface has been identified as the cause. It is also known that life can be enhanced by increasing capacitance of negative electrode. A bench-marking test cycle is used to explain these observations through a one-dimensional model. It is shown that, at the large discharge current densities used, faradaic reactions in the electrodes are spatially inhomogeneous, and charging is unable to reverse its effects. Consequently, lead sulfate deposit is larger on electrode's surface than at its center. Model uses a rate expression for charging modified to include diffusion of Pb 2+ , and predicts that sulfate continues to accumulate with cycling. A portion of electrode becomes inactive when volume fraction of sulfate reaches a critical value there. Battery fails when inactive area becomes large. It is shown that double-layer capacitance suppresses the non-uniformity in the faradaic reaction and alters the pattern of accumulation of sulfate. Negative electrode does not benefit from this since its capacitance is low. Sulfate accumulates in positive electrode also, but does not reach critical levels since positive electrode's capacitance is large. A large fraction of the demand for lead-acid batteries from automotive industries is for SLI application. But the demand is expected to decline as the auto industry moves toward Li batteries. However, as specifications become more stringent both on fuel economy and on emissions of green house gases, lead-acid battery has found a new application in stop-start technology of electric vehicles. Here, battery should be capable of rapid enough discharge to permit starting of the vehicle along with maintenance of other on-board electrical loads. Further, to facilitate charging by regenerative braking, the battery has to be in partial state of charge, which can be as low as 50%. This has come to be known as high rate partial-state-of-charge or for short, HRPSoC, duty. In the start-stop operation, the frequency of charging-discharging cycles is large. Equally importantly, while the discharge rate during cranking is about the same as in conventional SLI application, charging rate can be as large as thirty times more. The challenges faced in meeting this application have been well summarized by Moseley and Rand 1 and Moseley et al. 2 The main problem faced is the faster degradation of battery than encountered in the conventional SLI application. The diminished life has been attributed to accumulation of lead sulfate on the surface of the negative electrode. Conclusive evidence for this has been reported by Lam et al.3 based on tear-down analysis of failed batteries. Interestingly, it has been found that increasing the capacitance of the negative electrode enhances its life, and development of ultrabattery 4 is a well known demonstration of this. While a complete description of this device is not available in the open literature, it is s...

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“…Equation for φ is the same as used the earlier literature, 13,20,21,23 differences coming only through S.…”

Section: Charging-conversion Of Pbmentioning

confidence: 99%

“…Specific ion adsorption is not considered 21 and hence charging or discharging of double-layer does not affect mass balances. The mass balance for acid is given by [16] for the positive electrode and…”

Section: Charging-conversion Of Pbmentioning

confidence: 99%

Modeling of Effect of Double-Layer Capacitance and Failure of Lead-Acid Batteries in HRPSoC Application

Gandhi¹

2017

J. Electrochem. Soc.

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“…Reaction kinetics and cell voltage.-The simplest description of the reversible redox reactions taking place at the electrode surfaces is the Butler-Volmer expression for charge-transfer kinetics 18 j Pb = Fk 0 Pb c Pb͑II͒ͫ expͩ…”

Section: ͓24͔mentioning

confidence: 99%

A Mathematical Model for the Soluble Lead-Acid Flow Battery

Shah¹,

Li²,

Wills³

et al. 2010

J. Electrochem. Soc.

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The soluble lead-acid battery is a redox flow cell that uses a single reservoir to store the electrolyte and does not require a microporous separator or membrane, allowing a simpler design and a substantial reduction in cost. In this paper, a transient model for a reversible, lead-acid flow battery incorporating mass and charge transport and surface electrode reactions is developed. The charge-discharge behavior is complicated by the formation and subsequent oxidation of a complex oxide layer on the positive electrode surface, which is accounted for in the model. The full charge/discharge behavior over two cycles is simulated for many cases. Experiments measuring the cell voltage during repeated charge-discharge cycles are described, and the simulation results are compared to the laboratory data, demonstrating good agreement. The model is then employed to investigate the effects of variations in the current density on the performance of the battery. © 2010 The Electrochemical Society. ͓DOI: 10.1149/1.3328520͔ All rights reserved. The pressing demand for clean and efficient energy conversion, storage, and delivery, particularly the demand for renewable energy, has generated considerable interest in bulk energy storage technologies. Promising candidates for meeting the future energy-storage needs, including microgeneration, include redox flow batteries ͑RFBs͒ and flow batteries. In conventional batteries, such as the static lead-acid and lithium-ion cells, energy is stored entirely in the electrode structure. Redox flow batteries store energy either in a liquid electrolyte solution containing different redox couples, as in the all-vanadium battery, or in both an electrolyte and on the electrode surfaces in the form of deposits, as in the zinc-cerium system. The bulk of the electrolyte is stored in ͑typically two͒ reservoirs external to the cell. 1 The energy capacity of the system is determined by the volume of electrolytes in the tanks, the reactant concentrations, and the active area of the electrodes, while the system power is limited mainly by the size of the stacks and the active electrode surface area. Flow batteries can use a porous electrode ͑flow-through design͒, or the electrolyte can flow past an activated electrode ͑flow-by design͒.The applications of RFBs are not limited to the exploitation of renewable energy resources from the environment on large scales. RFBs can potentially be used for load leveling and peak shaving, uninterruptible power supply, and emergency backup.2 Demand for electricity is variable, requiring that some power generation installations are operated only during periods of high demand, a highly expensive and inefficient solution. An integrated energy-delivery system that includes an energy storage capability would improve reliability and enhance the quality of the electricity supply. For the supplier, it affords greater flexibility and savings in costs. Surplus installations could be decommissioned with the remaining installations operated at an almost constant load; storage cells...

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“…In these cases the separation algorithms are complex and these parameters can be obtained from a set of data, only. The current interruption technique has been successfully applied to predict valveregulated lead acid (VRLA) battery resistances and time constants by Srinivasan et al [7]. They considered four different processes, i.e., the relaxations of electronic resistance of the separator, the resistance of the porous electrode, which is the sum of the electronic and ionic resistances, as well as the kinetic and mass transport resistances.…”

Section: Main Parameter Estimation Techniquesmentioning

confidence: 99%

Estimation of the characteristic parameters of proton exchange membrane fuel cells under normal operating conditions

Kriston

Inzelt

2007

J Appl Electrochem

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The aim of this work is the study of the effectiveness of different parameter estimation techniques for proton exchange membrane fuel cells (PEMFC) under normal operating conditions. The procedure for the estimation of the real time parameters described herein in good approximation meets the requirements posed regarding such techniques, i.e., to obtain data without interrupting the functioning of the fuel cell and to be as simple as possible. In this approach a fuel cell combined with a step-down voltage regulator system was analyzed and the potential relaxation was used to determine PEMFC electrochemical properties. A screening measurement technique was applied using the analysis of variance (ANOVA) to elucidate the effect of the different operating conditions on the obtained parameter, hence to validate the developed algorithm. The results show that the operating conditions of the step-down regulator device affect some parameters, but the weak correlations predict that the method can be used in real applications.

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

Cited by 61 publications

References 24 publications

Modeling of Effect of Double-Layer Capacitance and Failure of Lead-Acid Batteries in HRPSoC Application

Modeling of Effect of Double-Layer Capacitance and Failure of Lead-Acid Batteries in HRPSoC Application

A Mathematical Model for the Soluble Lead-Acid Flow Battery

Estimation of the characteristic parameters of proton exchange membrane fuel cells under normal operating conditions

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