Temperature Estimation of Lithium-Ion Battery Based on an Improved Magnetic Nanoparticle Thermometer

Zou, Dongyao; Li, Ming; Wang, Dandan; Li, Nana; Su, Rijian; Zhang, Pu; Gan, Yong; Cheng, Jingjing

doi:10.1109/access.2020.3007932

Cited by 7 publications

(6 citation statements)

References 36 publications

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“…Temperature-sensitive properties not involving the use of ionizing radiation include amplitude 20,[24][25][26] or phase 16,27 of one of the higher-order harmonics of the magnetization signal, the ratio between harmonics of the same signal, 19,28,29 the relaxation time of nanoparticles, 30 the viscosity of the host medium, 31 the proton resonance frequency or relaxation time as in MRI thermometry, 32 various ultrasonic properties. 14 Some techniques are applied in non-biological environments as well, as for instance in vehicle batteries 33,34 Measuring the temperature via the reversible changes of the magnetic properties of the same nanoparticles used to heat a tissue (mainly through the harmonics of the picked-up signal as in MPI/ MPS) is possibly the prevalent and most direct strategy, 16,19,20,[24][25][26][27][28][29] and one which can be equally applied to particles oating in a uid environment or rmly blocked in a tissue. However, operating frequencies typical of MPI/MPS do not match the ones needed to obtain a good heating performance, so that making use of just one frequency 26 to combine thermometry and hyperthermia may result in a non-optimal heating process.…”

Section: Introductionmentioning

confidence: 99%

Multifunctional effects in magnetic nanoparticles for precision medicine: combining magnetic particle thermometry and hyperthermia

2023

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Section: Introductionmentioning

confidence: 99%

Multifunctional effects in magnetic nanoparticles for precision medicine: combining magnetic particle thermometry and hyperthermia

2023

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“…Each different type of method has its advantages and limitations 53–57 . Therefore, a summary of all the prominent techniques would be very helpful to researchers and developers serving as a baseline for further research and as a guideline for selecting appropriate techniques suitable for a specific requirement 58–62 . However, such a summary with detailed discussion on current progress and explanation of the principles, applications, challenges, and future research scopes has not yet been presented in the literature.…”

Section: Introductionmentioning

confidence: 99%

“…[53][54][55][56][57] Therefore, a summary of all the prominent techniques would be very helpful to researchers and developers serving as a baseline for further research and as a guideline for selecting appropriate techniques suitable for a specific requirement. [58][59][60][61][62] However, such a summary with detailed discussion on current progress and explanation of the principles, applications, challenges, and future research scopes has not yet been presented in the literature. Therefore, this article covered the research gap by conducting a comprehensive review of the state-of-theart temperature prediction strategies using EIS reported in the literature so far.…”

Section: Introductionmentioning

confidence: 99%

Temperature prediction of lithium‐ion batteries based on electrochemical impedance spectrum: A review

Wang

Duan

et al. 2022

Intl J of Energy Research

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Summary With the rapid development of global electric vehicles, artificial intelligence, and aerospace, lithium‐ion batteries (LIBs) have become more and more widely used due to their high property. More and more disasters are caused by battery combustion. Among them, the temperature prediction of LIBs is the key to prevent the occurrence of fire. At present, using surface temperature sensor to measure the temperature of LIBs is the main method. High‐capacity LIB packs used in electric vehicles and grid‐tied stationary energy storage system essentially consist of thousands of individual LIB cells. Therefore, installing a physical sensor at each cell, especially at the cell core, is not practically feasible from the solution cost, space, and weight point of view. So developing a new method for battery temperature prediction has become an urgent problem to be solved. Electrochemical impedance spectroscopy (EIS) is a widely applied non‐destructive method of characterization of LIBs. In recent years, methods of predicting LIBs temperature by EIS have been developed. The prediction of LIBs temperature based on EIS has the advantages of high real‐time performance and prediction accuracy, and the device is simple and practical. The proposed method has a good development prospect in electric vehicles and other fields and can effectively solve the current problems of LIBs temperature prediction. Therefore, it is urgent to summarize these works to promote the next development. This review summarizes the main methods of using EIS to predict the temperature of LIBs in recent years, including the methods based on the impedance, phase shift, and intercept frequency. The principle and application of various methods are reviewed. The advantages and disadvantages of different methods and the future development direction are discussed. Highlights Use EIS to quickly and effectively predict the internal temperature changes of LIBs. No hardware temperature sensors and thermal model are required. The methods to predict battery temperature based on impedance, phase shift, and intercept frequency are reviewed.

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“…In [25], a fast non‐destructive method of magnetic field monitoring is introduced for detecting defects such as capacity fade and mechanical degradation inside a cell. Beside analysing the defects, magnetic field around the lithium‐ion cell has also provided useful information for temperature estimation in LIBs [26]. There are two main sources for the magnetic fields around the lithium‐ion cell: (1) surface currents in the electrode, and (2) charge transfer currents in the electrolyte.…”

Section: Introductionmentioning

confidence: 99%

“…There are two main sources for the magnetic fields around the lithium‐ion cell: (1) surface currents in the electrode, and (2) charge transfer currents in the electrolyte. The behaviour of these currents in a cell determines the magnetic field around a cell as is shown in [26], which provides significant insight of the cell operational state.…”

Section: Introductionmentioning

confidence: 99%

Analysis of current density in the electrode and electrolyte of lithium‐ion cells for ageing estimation applications

Javadipour

Mehran

2021

IET Smart Grid

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Lithium-ion battery is the commonly used energy storage technology in electric vehicles (EVs) because of its inexpensive manufacturing cost and high energy capacity. For optimal utilization of its capacity and lifetime, reliable state of health (SoH) monitoring solutions have to be included in the battery management system (BMS). SoH of a cell is affected by several reasons such as internal degradation or external damages that need to be estimated. This article analyses the current density in electrode and electrolyte of an EV lithium-ion cell using a simulation assisted method that leads to improvement in SoH estimation accuracy. The experimental results are analysed through the fusion of the magnetic field images captured by quantum fluxgate magnetometers, installed on the surface of the cell, together with the real-time simulation of the multi-physics model of the cell. The magnetic field sensors measure the magnetic field intensity with an accuracy of ±2 mT. The real-time simulation input data is updated from the measurements of both the magnetic field sensors and the battery cycler. The multi-physics model of the cell is developed in COMSOL modelling software, and real-time data fusion process is implemented on dSPACE Microlabbox real-time simulator. Results confirm that the proposed monitoring solution provides useful insight that can be employed in ageing estimation of EV batteries. This is an open access article under the terms of the Creative Commons Attribution-NonCommercial-NoDerivs License, which permits use and distribution in any medium, provided the original work is properly cited, the use is non-commercial and no modifications or adaptations are made.

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Temperature Estimation of Lithium-Ion Battery Based on an Improved Magnetic Nanoparticle Thermometer

Cited by 7 publications

References 36 publications

Multifunctional effects in magnetic nanoparticles for precision medicine: combining magnetic particle thermometry and hyperthermia

Multifunctional effects in magnetic nanoparticles for precision medicine: combining magnetic particle thermometry and hyperthermia

Temperature prediction of lithium‐ion batteries based on electrochemical impedance spectrum: A review

Analysis of current density in the electrode and electrolyte of lithium‐ion cells for ageing estimation applications

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