Lithium‐plating‐free fast charging of large‐format lithium‐ion batteries with reference electrodes

Liu, Jinhai; Chu, Zhengyu; Li, Haili; Ren, Dongsheng; Zheng, Yuejiu; Lu, Languang; Han, Xiao; Ouyang, Minggao

doi:10.1002/er.6375

Cited by 25 publications

(11 citation statements)

References 55 publications

(120 reference statements)

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“…As other examples of utilizing EP-based charging approaches, papers [86] and [87] get benefits of implanting reference electrodes to achieve a faster charging. It has been reported that [87] implanted reliable reference electrodes within the cells in order to provide anode potential signals throughout the charging process, whose performances were thoroughly investigated. Accordingly, both anode potential and temperature were strictly maintained within the safety regions with the charger current modulated.…”

Section: Electrochemical-parameter-based Charging Methodsmentioning

confidence: 99%

Charging control strategies for lithium‐ion battery packs: Review and recent developments

Ghaeminezhad

Monfared

2021

IET Power Electronics

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The expanding use of lithium-ion batteries in electric vehicles and other industries has accelerated the need for new efficient charging strategies to enhance the speed and reliability of the charging process without decaying battery performance indices. Numerous attempts have been conducted to establish optimal charging techniques for commercial lithium-ion batteries during the last decade. However, a few of them are devoted to the comprehensive analysis and comparison of the charging techniques from the controloriented perspective for a battery pack. To fill this gap, a review of the most up-to-date charging control methods applied to the lithium-ion battery packs is conducted in this paper. They are broadly classified as non-feedback-based, feedback-based, and intelligent charging methods. Finally, the paper concludes with a comprehensive discussion of the strengths and weaknesses of the reviewed techniques. INTRODUCTIONRenewable and clean energy sources are necessary to assist in developing sustainable power that supplies plenty of possible innovative technologies, such as electric vehicles (EVs), solar and wind power systems [1,2]. They must reduce our current reliance on some limited sources of energy such as fossil fuel and uranium to alleviate worries about energy, environment, and economy [3]. Consequently, the need for storage has raised up dramatically while rechargeable electrochemical batteries are employed in practically every energy storing device [4].Recent advancements in lithium-ion batteries demonstrate that they exhibit some advantages over other types of rechargeable batteries, including greater power density and higher cell voltages, lower maintenance requirements, longer lifetime, and faster-charging speeds with lower self-discharge rates [5,6]. However, some drawbacks limit the broad adaption of the lithium-ion batteries, associated explicitly with their high cost, short life-cycle, constrained performance temperature, and possible safety infractions caused by overcharge, over-discharge, short circuit, and production defects [5,7]. In addition, a single lithium-ion cell's voltage is limited in the range of 2.4-4.2 V [8], which is not enough for high voltage demand in practical applications; hence, they are usually connected in series as aThis is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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Section: Electrochemical-parameter-based Charging Methodsmentioning

confidence: 99%

Charging control strategies for lithium‐ion battery packs: Review and recent developments

Ghaeminezhad

Monfared

2021

IET Power Electronics

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“…Liu et al [16] introduced a novel fast-charging approach that hinges on real-time monitoring of the negative electrode potential and adjusting the charging current dynamically. The negative electrode potential is measured by a reference electrode inserted between the anode and cathode and shielded by a separator (Figure 2).…”

Section: Sensing Of Internal Electrode Potentialmentioning

confidence: 99%

Advancing Smart Lithium-Ion Batteries: A Review on Multi-Physical Sensing Technologies for Lithium-Ion Batteries

Wang,

Liu,

et al. 2024

Energies

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Traditional battery management systems (BMS) encounter significant challenges, including low precision in predicting battery states and complexities in managing batteries, primarily due to the scarcity of collected signals. The advancement towards a “smart battery”, equipped with diverse sensor types, promises to mitigate these issues. This review highlights the latest developments in smart sensing technologies for batteries, encompassing electrical, thermal, mechanical, acoustic, and gas sensors. Specifically, we address how these different signals are perceived and how these varied signals could enhance our comprehension of battery aging, failure, and thermal runaway mechanisms, contributing to the creation of BMS that are safer and more reliable. Moreover, we analyze the limitations and challenges faced by different sensor applications and discuss the advantages and disadvantages of each sensing technology. Conclusively, we present a perspective on overcoming future hurdles in smart battery development, focusing on appropriate sensor design, optimized integration processes, efficient signal transmission, and advanced management systems.

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“…However, it's important to acknowledge that realworld conditions can introduce losses during the charging process. Observations have shown that approximately 40% of these losses occur during battery charging because the battery is not an ideal voltage source [39], [40]. However, charging efficiency can vary based on various factors including the type of battery, the state of charge, temperature, and the quality of the charger.…”

Section: B Battery Charging Current and Charging Duration Specificationsmentioning

confidence: 99%

IoT-Enabled Water Monitoring in Smart Cities With Retrofit and Solar-Based Energy Harvesting

Bawankar,

Kriti,

Chouhan

et al. 2024

IEEE Access

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Monitoring water flow helps to identify leaks and wastage, leading to better management of water resources and conservation of this precious resource. To address this challenge, there is a need for an efficient and sustainable water management system. This paper presents an Internet of Things (IoT) based solution that involves retrofitting existing analog water meters using readily available off-the-shelf electronic components. Real-time data collection and analysis are performed through edge computation, which locally processes water meter images captured by the camera and extracts water meter readings. These readings are transmitted to the cloud for storage and further analysis. Various strategies have been implemented to optimize supply-current usage, preserving charge-discharge cycles of solar-powered batteries even in adverse environmental conditions. To streamline the firmware update process for multiple connected devices, a broadcasting technique is employed, offering the benefits of reduced manual labor and time savings. To assess the reliability and performance of developed solution, field deployment is conducted over several months, enabling the characterization of water usage patterns across different locations. Integrating energy harvesting capabilities into system reduces maintenance costs and promotes eco-friendly energy practices. Overall, this solution offers an effective and comprehensive approach towards achieving efficient and sustainable water management.

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Lithium‐plating‐free fast charging of large‐format lithium‐ion batteries with reference electrodes

Cited by 25 publications

References 55 publications

Charging control strategies for lithium‐ion battery packs: Review and recent developments

Charging control strategies for lithium‐ion battery packs: Review and recent developments

Advancing Smart Lithium-Ion Batteries: A Review on Multi-Physical Sensing Technologies for Lithium-Ion Batteries

IoT-Enabled Water Monitoring in Smart Cities With Retrofit and Solar-Based Energy Harvesting

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