Your search keyword '"NMC"' showing total 21 results

1. LAREX-Tupy Process: Recycling of Li-Ion Batteries from Electric Vehicles by Hydrometallurgical Route Towards Circular Economy

Author

Botelho Junior, Amilton Barbosa, da Silva, David Vasconcelos, Lima, Anastássia Mariáh Nunes de Oliveira, de Oliveira, Rafael Piumatti, Gobo, Luciana Assis, Kumoto, Elio Augusto, Ferrarese, Andre, Tenório, Jorge Alberto Soares, Espinosa, Denise Crocce Romano, and The Minerals, Metals & Materials Society

Published

2024

2. Testing of NMC and LFP Li-ION cells for surface temperature at various conditions

Author

Ognjen Popović, Veljko Rupar, Željko Praštalo, Snežana Aleksandrović, and Vladimir Milisavljević

Subjects

Battery electric vehicles, Heat load, Li-ion cells, NMC, LFP, Cell's surface temperature, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Battery electric vehicles (BEVs) are being considered as a replacement technology for diesel vehicles in underground mining of mineral resources. However, many issues related to BEVs in industrial applications still require more detailed research. One significant topic is the heat load—BEVs' heat emission into the working environment during regular operation. This paper provides an overview of the thermal behavior of NMC and LFP Li-ion cells tested under various conditions, which is an important step in determining the overall heat load of BEVs. The surface temperature of three NMC and one LFP 18650 Li-ion cells was monitored during charging and discharging at four different rates, at constant ambient temperatures of 30 °C and 40 °C. The main results pertain to the cell's thermal behavior during charging and discharging, highlighting the distinctive temperature profiles of NMC and LFP cells.

Published

2024

3. Evaluating the Aging-Induced Voltage Slippery as Cause for Float Currents of Lithium-ion Cells.

Author

Azzam, Mohamed, Endisch, Christian, and Lewerenz, Meinert

Subjects

VOLTAGE, SOLID electrolytes, LITHIUM-ion batteries, HIGH voltages, LITHIATION, TEST methods

Abstract

This paper provides a comprehensive exploration of float current analysis in lithium-ion batteries, a promising new testing method to assess calendar aging. Float currents are defined as the steady-state trickle charge current after a transient part. In the literature, a correlation to capacity loss was reported. Assuming the float current compensates for the voltage decay over time and is linked to calendar aging, effects from voltage slippery must be considered. The dU/dQ analysis suggests solely a loss of active lithium. Therefore, we investigate the solid electrolyte interphase (SEI) growth as the general aging mechanism to explain the origin of float currents. Our results show that the voltage slippery theory holds true within the low to middle test voltage ranges. However, the theory's explanatory power begins to diminish at higher voltage ranges, suggesting the existence of additional, yet unidentified, factors influencing the float current. A shuttle reaction or lithiation of the cathode by electrolyte decomposition are the most promising alternative aging mechanisms at high voltages. The paper proposes a unique voltage slippery model to check for correlations between aging mechanisms, the float current test and the check-up test. For a better understanding, test strategies are proposed to verify/falsify the aging mechanisms beyond SEI. [ABSTRACT FROM AUTHOR]

Published

2024

4. Long-Term Self-Discharge Measurements and Modelling for Various Cell Types and Cell Potentials.

Author

Azzam, Mohamed, Ehrensberger, Moritz, Scheuer, Reinhard, Endisch, Christian, and Lewerenz, Meinert

Subjects

*VOLTAGE, *ANODES

Abstract

Self-discharge of lithium-ion cells leads to voltage decay over time. In this work, the self-discharge was measured at 30 °C for three cell types at various voltage levels for about 150 days in a constant voltage mode determining the current at a high precision (float current). All cells exhibit a transient part leading to a steady-state, which is no longer influenced by reversible effects. To study the effect of the check-ups on the steady-state float current, the cells, interrupted and not interrupted by check-ups, were compared. The results indicate that both the transient processes and steady-state currents are highly reproducible. In the first period of the float current, the polarization dominates the measured current, followed by the anode overhang effect dominating the process for a period of 5–30 days. After the decline of both processes, a mostly constant steady-state in the order of µA is observed. The check-up interruption generally shows no apparent effect on the reached steady-state and results only in an extended settling time. A model to simulate the transient process and steady-state of float currents was developed. The model shows a high accuracy in reproducing the results and identifying the time needed to reach the steady-state. [ABSTRACT FROM AUTHOR]

Published

2023

5. Evaluating the Aging-Induced Voltage Slippery as Cause for Float Currents of Lithium-ion Cells

Author

Mohamed Azzam, Christian Endisch, and Meinert Lewerenz

Subjects

18650, NCA, NMC, LFP, graphite, float current analysis, Production of electric energy or power. Powerplants. Central stations, TK1001-1841, Industrial electrochemistry, TP250-261

Abstract

This paper provides a comprehensive exploration of float current analysis in lithium-ion batteries, a promising new testing method to assess calendar aging. Float currents are defined as the steady-state trickle charge current after a transient part. In the literature, a correlation to capacity loss was reported. Assuming the float current compensates for the voltage decay over time and is linked to calendar aging, effects from voltage slippery must be considered. The dU/dQ analysis suggests solely a loss of active lithium. Therefore, we investigate the solid electrolyte interphase (SEI) growth as the general aging mechanism to explain the origin of float currents. Our results show that the voltage slippery theory holds true within the low to middle test voltage ranges. However, the theory’s explanatory power begins to diminish at higher voltage ranges, suggesting the existence of additional, yet unidentified, factors influencing the float current. A shuttle reaction or lithiation of the cathode by electrolyte decomposition are the most promising alternative aging mechanisms at high voltages. The paper proposes a unique voltage slippery model to check for correlations between aging mechanisms, the float current test and the check-up test. For a better understanding, test strategies are proposed to verify/falsify the aging mechanisms beyond SEI.

Published

2023

6. Insights into the Electrochemical Performance of 1.8 Ah Pouch and 18650 Cylindrical NMC:LFP|Si:C Blend Li-ion Cells.

Author

Landa-Medrano, Imanol, Eguia-Barrio, Aitor, Sananes-Israel, Susan, Porcher, Willy, Trad, Khiem, Moretti, Arianna, Carvalho, Diogo Vieira, Passerini, Stefano, and de Meatza, Iratxe

Subjects

NEGATIVE electrode, RENEWABLE energy sources, SCANNING electron microscopy, LITHIUM-ion batteries

Abstract

Silicon has become an integral negative electrode component for lithium-ion batteries in numerous applications including electric vehicles and renewable energy sources. However, its high capacity and low cycling stability represent a significant trade-off that limits its widespread implementation in high fractions in the negative electrode. Herein, we assembled high-capacity (1.8 Ah) cells using a nanoparticulate silicon–graphite (1:7.1) blend as the negative electrode material and a LiFePO4–LiNi0.5Mn0.3Co0.2O2 (1:1) blend as the positive electrode. Two types of cells were constructed: cylindrical 18650 and pouch cells. These cells were subjected both to calendar and cycling aging, the latter exploring different working voltage windows (2.5–3.6 V, 3.6–4.5 V, and 2.5–4.5 V). In addition, one cell was opened and characterised at its end of life by means of X-ray diffraction, scanning electron microscopy, and further electrochemical tests of the aged electrodes. Si degradation was identified as the primary cause of capacity fade of the cells. This work highlights the need to develop novel strategies to mitigate the issues associated with the excessive volumetric changes of Si. [ABSTRACT FROM AUTHOR]

Published

2022

7. Long-Term Self-Discharge Measurements and Modelling for Various Cell Types and Cell Potentials

Author

Mohamed Azzam, Moritz Ehrensberger, Reinhard Scheuer, Christian Endisch, and Meinert Lewerenz

Subjects

18650, NCA, NMC, LFP, graphite, float current analysis, Technology

Abstract

Self-discharge of lithium-ion cells leads to voltage decay over time. In this work, the self-discharge was measured at 30 ∘C for three cell types at various voltage levels for about 150 days in a constant voltage mode determining the current at a high precision (float current). All cells exhibit a transient part leading to a steady-state, which is no longer influenced by reversible effects. To study the effect of the check-ups on the steady-state float current, the cells, interrupted and not interrupted by check-ups, were compared. The results indicate that both the transient processes and steady-state currents are highly reproducible. In the first period of the float current, the polarization dominates the measured current, followed by the anode overhang effect dominating the process for a period of 5–30 days. After the decline of both processes, a mostly constant steady-state in the order of μA is observed. The check-up interruption generally shows no apparent effect on the reached steady-state and results only in an extended settling time. A model to simulate the transient process and steady-state of float currents was developed. The model shows a high accuracy in reproducing the results and identifying the time needed to reach the steady-state.

Published

2023

8. The Electrochemical Performance and Applications of Several Popular Lithium-ion Batteries for Electric Vehicles - A Review

Author

Liu, Xuan, Li, Kang, Li, Xiang, Barbosa, Simone Diniz Junqueira, Series Editor, Filipe, Joaquim, Series Editor, Kotenko, Igor, Series Editor, Sivalingam, Krishna M., Series Editor, Washio, Takashi, Series Editor, Yuan, Junsong, Series Editor, Zhou, Lizhu, Series Editor, Li, Kang, editor, Zhang, Jianhua, editor, Chen, Minyou, editor, Yang, Zhile, editor, and Niu, Qun, editor

Published

2018

9. Comparative Study of Equivalent Circuit Models Performance in Four Common Lithium-Ion Batteries: LFP, NMC, LMO, NCA.

Author

Tran, Manh-Kien, DaCosta, Andre, Mevawalla, Anosh, Panchal, Satyam, and Fowler, Michael

Subjects

LITHIUM-ion batteries, ELECTRIC vehicle batteries, BATTERY management systems, ELECTRIC batteries, ENERGY storage, COMPARATIVE studies

Abstract

Lithium-ion (Li-ion) batteries are an important component of energy storage systems used in various applications such as electric vehicles and portable electronics. There are many chemistries of Li-ion battery, but LFP, NMC, LMO, and NCA are four commonly used types. In order for the battery applications to operate safely and effectively, battery modeling is very important. The equivalent circuit model (ECM) is a battery model often used in the battery management system (BMS) to monitor and control Li-ion batteries. In this study, experiments were performed to investigate the performance of three different ECMs (1RC, 2RC, and 1RC with hysteresis) on four Li-ion battery chemistries (LFP, NMC, LMO, and NCA). The results indicated that all three models are usable for the four types of Li-ion chemistries, with low errors. It was also found that the ECMs tend to perform better in dynamic current profiles compared to non-dynamic ones. Overall, the best-performed model for LFP and NCA was the 1RC with hysteresis ECM, while the most suited model for NMC and LMO was the 1RC ECM. The results from this study showed that different ECMs would be suited for different Li-ion battery chemistries, which should be an important factor to be considered in real-world battery and BMS applications. [ABSTRACT FROM AUTHOR]

Published

2021

10. Insights into the Electrochemical Performance of 1.8 Ah Pouch and 18650 Cylindrical NMC:LFP|Si:C Blend Li-ion Cells

Author

Imanol Landa-Medrano, Aitor Eguia-Barrio, Susan Sananes-Israel, Willy Porcher, Khiem Trad, Arianna Moretti, Diogo Vieira Carvalho, Stefano Passerini, and Iratxe de Meatza

Subjects

lithium-ion batteries, silicon graphite anodes, LFP, NMC, electrode manufacturing, cell formats, Production of electric energy or power. Powerplants. Central stations, TK1001-1841, Industrial electrochemistry, TP250-261

Abstract

Silicon has become an integral negative electrode component for lithium-ion batteries in numerous applications including electric vehicles and renewable energy sources. However, its high capacity and low cycling stability represent a significant trade-off that limits its widespread implementation in high fractions in the negative electrode. Herein, we assembled high-capacity (1.8 Ah) cells using a nanoparticulate silicon–graphite (1:7.1) blend as the negative electrode material and a LiFePO4–LiNi0.5Mn0.3Co0.2O2 (1:1) blend as the positive electrode. Two types of cells were constructed: cylindrical 18650 and pouch cells. These cells were subjected both to calendar and cycling aging, the latter exploring different working voltage windows (2.5–3.6 V, 3.6–4.5 V, and 2.5–4.5 V). In addition, one cell was opened and characterised at its end of life by means of X-ray diffraction, scanning electron microscopy, and further electrochemical tests of the aged electrodes. Si degradation was identified as the primary cause of capacity fade of the cells. This work highlights the need to develop novel strategies to mitigate the issues associated with the excessive volumetric changes of Si.

Published

2022

11. Lithium-Ion Electrochemical Energy Storage: the Current State, Problems, and Development Trends in Russia.

Author

Antipov, E. V., Abakumov, A. M., Drozhzhin, O. A., and Pogozhev, D. V.

Abstract

Analysis of the state and trends of the world market of lithium-ion batteries (LIB) is carried out, and the main development trends are identified. Until recently, the growth basis of the global LIB market was built on requests related to portable electronics, but the saturation of this market and the formation of new needs in the emerging areas of the automotive industry, industrial generation, and network power distribution have changed the development vector of the entire industry. New needs have made adjustments to key requirements for battery systems and determined new technological barriers. The present work describes and classifies the main LIB electrode components as well as their applicability depending on the field of use of the final product. The state of the Russian market of both final products and main electrode materials is considered. Despite optimistic forecasts for the development of the LIB market in Russia and the expected significant economic effect, the current level of competences, technologies, and production volumes in the Russian Federation does not meet the needs of modern and future markets. In 2017, LIB import to Russia amounted to $85.1 million USD with an annual consumption growth rate of approximately 15–25%. The structure of the battery import is dominated by batteries for consumer electronics. The share of domestic manufacturers in the civil sector is less than 3%, and domestic manufacturers are mainly represented in the special equipment sector. The work presents a list of the main manufacturers of lithium-ion batteries dominating the Russian market. The tendencies to reduce the cost of existing solutions and the possibility of switching to alternative lithium-free metal-ion batteries are considered. [ABSTRACT FROM AUTHOR]

Published

2019

12. Comparative Study of Surface Temperature Behavior of Commercial Li-Ion Pouch Cells of Different Chemistries and Capacities by Infrared Thermography

Author

Shovon Goutam, Jean-Marc Timmermans, Noshin Omar, Peter Van den Bossche, and Joeri Van Mierlo

Subjects

surface temperature, spatial distribution, infrared thermography, NMC, LFP, LTO, thermal management, Technology

Abstract

The non-uniform surface temperature distribution of a battery cell results from complex reactions inside the cell and makes efficient thermal management a challenging task. This experimental work attempts to determine the evolution of surface temperature distribution of three pouch type commercial cells: Nickel Manganese Cobalt oxide (NMC)-based 20 Ah cell, Lithium Iron Phosphate (LFP) 14 Ah, and Lithium Titanate Oxide (LTO) 5 Ah battery cell by using contact thermistor and infrared (IR) thermography. High current (up to 100 A) continuous charge/discharge and high current (80 A) micro pulse cycling profile were applied on the cells. It was found that thermistor based temperature profile varied cell to cell, especially the LTO cell. Among the investigated cells, the NMC cell shows highest temperature rise and the LTO cell the lowest rise. IR (Infrared) images revealed the spatial distribution of surface temperature, in particular the location of the hottest region varies depending not only on the geometrical and material properties of the cell, but also the type of loads applied on the cells. Finally, a modeling perspective of the cell temperature non-uniformity is also discussed.

Published

2015

13. Development of a Two-Dimensional-Thermal Model of Three Battery Chemistries.

Author

Jaguemont, Joris, Nikolian, Alexandros, Omar, Noshin, Goutam, Shovon, Van Mierlo, Joeri, and Van den Bossche, Peter

Subjects

*LITHIUM-ion batteries, *THERMAL analysis, *HYBRID electric vehicles

Abstract

The growing need for accurate estimation of by fitting battery's thermal and electrical performances at different operating conditions is crucial in its applications especially in electrified vehicles. This paper presents an effective method for developing a thermal and electrical modeling methodology for calculation thermal behavior of a lithium-ion cell and the voltage response under a current solicitation. The model was elaborated on three pouch cells with different battery chemistries for use in electrical vehicles/hybrid electrical vehicles, namely lithium iron phosphate, lithium nickel manganese cobalt oxide, and lithium titanium oxide (LTO). The model, implemented in a MATLAB/Simulink interface, uses an equivalent circuit and heat-generation equations coupled a thermal model. The three cell chemistries have been investigated using test procedures and thermal images at room temperature. The results of this study show that a temperature distribution to be fairly uniform after a complete discharge for the three chemistries with the lowest temperature gradient found for the LTO-based cell. Finally, comparison between simulation results and measured data under dynamic profiles shows a good correspondence with the measurements of the validation tests with errors lying between ±4% and 2 °C for the electrical and thermal model, respectively. [ABSTRACT FROM AUTHOR]

Published

2017

14. Comparative Study of Equivalent Circuit Models Performance in Four Common Lithium-Ion Batteries: LFP, NMC, LMO, NCA

Author

Satyam Panchal, Anosh Mevawalla, Manh-Kien Tran, Michael Fowler, and Andre DaCosta

Subjects

Battery (electricity), TK1001-1841, Materials science, 020209 energy, cell chemistry, Energy Engineering and Power Technology, chemistry.chemical_element, LFP, 02 engineering and technology, lithium-ion battery, 7. Clean energy, Automotive engineering, Lithium-ion battery, Energy storage, Battery management systems, Production of electric energy or power. Powerplants. Central stations, 0202 electrical engineering, electronic engineering, information engineering, Electrochemistry, Electronics, Electrical and Electronic Engineering, NMC, LMO, NCA, 021001 nanoscience & nanotechnology, battery modeling, hysteresis effect, TP250-261, chemistry, Industrial electrochemistry, equivalent circuit model, Equivalent circuit, Lithium, 0210 nano-technology

Abstract

Lithium-ion (Li-ion) batteries are an important component of energy storage systems used in various applications such as electric vehicles and portable electronics. There are many chemistries of Li-ion battery, but LFP, NMC, LMO, and NCA are four commonly used types. In order for the battery applications to operate safely and effectively, battery modeling is very important. The equivalent circuit model (ECM) is a battery model often used in the battery management system (BMS) to monitor and control Li-ion batteries. In this study, experiments were performed to investigate the performance of three different ECMs (1RC, 2RC, and 1RC with hysteresis) on four Li-ion battery chemistries (LFP, NMC, LMO, and NCA). The results indicated that all three models are usable for the four types of Li-ion chemistries, with low errors. It was also found that the ECMs tend to perform better in dynamic current profiles compared to non-dynamic ones. Overall, the best-performed model for LFP and NCA was the 1RC with hysteresis ECM, while the most suited model for NMC and LMO was the 1RC ECM. The results from this study showed that different ECMs would be suited for different Li-ion battery chemistries, which should be an important factor to be considered in real-world battery and BMS applications.

Published

2021

15. Comparative Study of Surface Temperature Behavior of Commercial Li-Ion Pouch Cells of Different Chemistries and Capacities by Infrared Thermography.

Author

Goutam, Shovon, Timmermans, Jean-Marc, Omar, Noshin, Den Bossche, Peter Van, and Van Mierlo, Joeri

Subjects

*SURFACE temperature, *LITHIUM-ion batteries, *INFRARED photography, *THERMOGRAPHY, *THERMAL management (Electronic packaging)

Abstract

The non-uniform surface temperature distribution of a battery cell results from complex reactions inside the cell and makes efficient thermal management a challenging task. This experimental work attempts to determine the evolution of surface temperature distribution of three pouch type commercial cells: Nickel Manganese Cobalt oxide (NMC)-based 20 Ah cell, Lithium Iron Phosphate (LFP) 14 Ah, and Lithium Titanate Oxide (LTO) 5 Ah battery cell by using contact thermistor and infrared (IR) thermography. High current (up to 100 A) continuous charge/discharge and high current (80 A) micro pulse cycling profile were applied on the cells. It was found that thermistor based temperature profile varied cell to cell, especially the LTO cell. Among the investigated cells, the NMC cell shows highest temperature rise and the LTO cell the lowest rise. IR (Infrared) images revealed the spatial distribution of surface temperature, in particular the location of the hottest region varies depending not only on the geometrical and material properties of the cell, but also the type of loads applied on the cells. Finally, a modeling perspective of the cell temperature non-uniformity is also discussed. [ABSTRACT FROM AUTHOR]

Published

2015

16. Full suite of lithium products will be required to power global energy transition, conference is told.

Author

Perry, Callum

Subjects

RENEWABLE energy transition (Government policy), LITHIUM, ENERGY consumption, LITHIUM cells, RAW materials

Abstract

A range of different battery chemistries and, therefore, different lithium products, will be required to meet global energy transition demands, panelists told delegates in the US at Fastmarkets' Lithium Supply & Battery Raw Materials conference this week. [ABSTRACT FROM AUTHOR]

Published

2022

17. Baterias de Iões de Lítio, a chave da Eletrificação Automóvel

Author

Fragoso, Henrique, Nogueira, Teresa, and Repositório Científico do Instituto Politécnico do Porto

Subjects

Veículo Elétrico, NCA, LFP, Bateria de Iões de Lítio, NMC

Abstract

A mobilidade da sociedade do s��culo XXI levanta quest��es de sustentabilidade energ��tica, tanto a n��vel da produ����o de energia como do seu armazenamento. As baterias de i��es - l��tio s��o um dos sistemas de armazenamento qu��mico de energia mais relevantes da atualidade com aplica����o nos mais diversos dispositivos el��tricos e eletr��nicos e, recentemente, nos ve��culos el��tricos e h��bridos. Comparativamente a outros sistemas, estas baterias destacam-se por serem leves e com elevado potencial el��trico, entre outras carater��sticas vantajosas que se descrevem. Neste artigo s��o apresentadas e comparadas 3 tecnologias de baterias de i��es de l��tio utilizadas na ind��stria autom��vel, com uma reflex��o sobre as necessidades tecnol��gicas a desenvolver nos pr��ximos anos, Neutro �� Terra, N.�� 24 (2019): Revista T��cnico-Cient��fica (Segundo Semestre)

Published

2019

18. A Comparative Study on Open Circuit Voltage Models for Lithium-ion Batteries

Author

Yu, Quan-Qing, Xiong, Rui, Wang, Le-Yi, and Lin, Cheng

Published

2018

19. Battery, EV producers grapple with record-high prices due to ongoing raw-material supply crunch.

Author

Yang, Justin and Ghilotti, Davide

Subjects

SUPPLY chain disruptions, RAW materials, CARBON dioxide mitigation, STORAGE batteries

Abstract

Battery producers will have to grapple with historically high prices across different chemistries with most raw material prices facing a deepening supply crunch, potentially making decarbonization of the transportation sector more expensive in the longer term. [ABSTRACT FROM AUTHOR]

Published

2022

20. Development of a Two-Dimensional-Thermal Model of Three Battery Chemistries

Author

Peter Van Den Bossche, Shovon Goutam, Joeri Van Mierlo, Noshin Omar, Alexandros Nikolian, Joris Jaguemont, Electrical Engineering and Power Electronics, Electromobility research centre, Faculty of Engineering, Industrial Sciences and Technology, and Engineering Technology

Subjects

Battery (electricity), Chemical substance, 020209 energy, Nuclear engineering, Lithium iron phosphate, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, LFP, thermal model, Temperature measurement, chemistry.chemical_compound, chemistry, Thermal, 0202 electrical engineering, electronic engineering, information engineering, Equivalent circuit, Lithium, LTO, Electrical and Electronic Engineering, entropy, Cobalt oxide, NMC, temperature predictions

Abstract

The growing need for accurate estimation of b By fitting attery’s thermal and electrical performances at different operating conditions are crucial in its applications especially in electrified vehicles. This paper presents an effective method for developing a thermal and electrical modelling methodology for calculation thermal behavior of a lithium-ion (Li-ion) cell and the voltage response under a current solicitation. The model was elaborated on three pouch cells with different battery chemistries for use in electrical vehicles/hybrid electrical vehicles, namely: lithium iron phosphate (LFP), lithium nickel manganese cobalt oxide (NMC) and lithium titanium oxide (LTO). The model, implemented in a Matlab/Simulink interface, uses an equivalent circuit and heat generation equations coupled a thermal model. The three cell chemistries have been investigated using test procedures and thermal images at room temperature. The results of this study show that a temperature distribution to be fairly uniform after a complete discharge for the three chemistries with the lowest temperature gradient found for the LTO-based cell. Finally, comparison between simulation results and measured data under a dynamic profiles shows a good correspondence with the measurements of the validation tests with errors lying between ±4% and 2°C for the electrical and thermal model, respectively., The growing need for accurate estimation of b By fitting attery’s thermal and electrical performances at different operating conditions are crucial in its applications especially in electrified vehicles. This paper presents an effective method for developing a thermal and electrical modelling methodology for calculation thermal behavior of a lithium-ion (Li-ion) cell and the voltage response under a current solicitation. The model was elaborated on three pouch cells with different battery chemistries for use in electrical vehicles/hybrid electrical vehicles, namely: lithium iron phosphate (LFP), lithium nickel manganese cobalt oxide (NMC) and lithium titanium oxide (LTO). The model, implemented in a Matlab/Simulink interface, uses an equivalent circuit and heat generation equations coupled a thermal model. The three cell chemistries have been investigated using test procedures and thermal images at room temperature. The results of this study show that a temperature distribution to be fairly uniform after a complete discharge for the three chemistries with the lowest temperature gradient found for the LTO-based cell. Finally, comparison between simulation results and measured data under a dynamic profiles shows a good correspondence with the measurements of the validation tests with errors lying between ±4% and 2°C for the electrical and thermal model, respectively

Published

2017

21. Water uptake of tape-cast cathodes for lithium ion batteries

Author

Langklotz, U., Schneider, M., Michaelis, A., and Publica

Subjects

residual water, solid electrolyte interface, LFP, lithium ion battery, NMC

Abstract

High-performance ceramic-based cathodes (e.g. NMC, LFP) are the backbone of lithium ion batteries. The production of cathodes is based on ceramic manufacturing technologies (powder processing, slurry, tape casting). The minimization of the water content in the fabricated battery is a crucial point in its manufacturing. This work is focused on the kinetics of water uptake in tape-cast cathode materials (NMC, LFP). The cathode foils were exposed to atmospheres with varying humidity and the water content was determined by means of coulometric Karl-Fischer titration. Conversely, the tendency of the cathodes to release residual water is examined. Additionally, electrochemical investigations were performed on cathode foils containing defined amounts of water. Galvanostatic charge-discharge experiments were conducted in 2-electrode Swagelok® cells versus graphite anodes. It could be shown that the influence of residual water on the cell performance is very complex. On the one hand, the residual water causes side reactions. On the other hand, low water content obviously supports the formation of the solid electrolyte interface (SEI) on the anode.

Published

2013