An integrated framework for minimization of inter lithium‐ion cell temperature differences and the total volume of the cell of battery pack for electric vehicles

Liu, Yun; Maddila, Sivasriprasanna; Gao, Liang; Peng, Xiongbin; Niu, Xiaodong; Garg, Akhil; Chin, Christina

doi:10.1002/est2.41

Cited by 9 publications

(4 citation statements)

References 30 publications

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“…However, most of the green energy sources are intermittent and random, such as wind and solar, which calls for the affordable smart grids and the rechargeable battery technologies. As the most successful energy storage devices, lithium-ion batteries (LIBs) have been widely used in our daily life, including electric vehicles and wearable electronic devices; thus, they have been well recognized by the 2019 Nobel Prize in Chemistry. However, LIBs faced a huge challenge for the use in the grid-scale energy storage with massive production because of the flammable electrolyte and high cost. − Recently, several types of rechargeable batteries have the potential to be used for electricity grid systems, which are sodium-ion batteries, , potassium-ion batteries, − and various aqueous batteries. − Considering the price and safety, the aqueous rechargeable metal-ion batteries should be a better choice for grid-scale energy storage.…”

Section: Introductionmentioning

confidence: 99%

“…1 However, most of the green energy sources are intermittent and random, such as wind and solar, which calls for the affordable smart grids and the rechargeable battery technologies. As the most successful energy storage devices, lithium-ion batteries (LIBs) have been widely used in our daily life, 2 including electric vehicles and wearable electronic devices; 3 thus, they have been well recognized by the 2019 Nobel Prize in Chemistry. However, LIBs faced a huge challenge for the use in the grid-scale energy storage with massive production because of the flammable electrolyte and high cost.…”

Section: ■ Introductionmentioning

confidence: 99%

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Boosted Charge Transfer in Twinborn α-(Mn₂O₃–MnO₂) Heterostructures: Toward High-Rate and Ultralong-Life Zinc-Ion Batteries

Long

Yang

Cuan

et al. 2020

ACS Appl. Mater. Interfaces

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Aqueous ZIBs are one of the most promising nextgeneration rechargeable batteries because of the high capacity, high hydrogen evolution overpotential, and chemically stable reversible plating/stripping of the zinc electrode in the mild aqueous electrolyte. However, there are limited cathode materials that can store Zn 2+ reversibly with superior cycling and rate capability. Herein, hierarchically porous nanorods composed of twinborn α-(Mn 2 O 3 −MnO 2 ) heterostructures are proposed as a robust cathode for Zn storage. Thanks to the hierarchically porous nanorod morphology and the abundant interface of the heterostructures involving a built-in electric field, the as-obtained twinborn α-(Mn 2 O 3 −MnO 2 ) electrode delivers a high capacity of 170 mA h g −1 for 2000 cycles at 500 mA g −1 and shows an excellent rate capability of up to 1.5 A g −1 with a capacity of 124 mA h g −1 . The inspiring results achieved exhibit the enormous potential of the highperformance heterostructure cathode for fast and stable ZIBs.

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Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

Boosted Charge Transfer in Twinborn α-(Mn₂O₃–MnO₂) Heterostructures: Toward High-Rate and Ultralong-Life Zinc-Ion Batteries

Long

Yang

Cuan

et al. 2020

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

show abstract

“…Therefore, it is necessary to improve the flexibility and flexibility of the disassembly process to achieve the safety index of battery disassembly, resulting in personal injury and property damage. 30 Therefore, the safety and efficiency of the battery pack disassembly process need to be carefully studied. Replacing workers with industrial robots is an excellent research direction.…”

Section: Solving the Safety Problems In The Battery Dismantling Process Of Electric Vehiclementioning

confidence: 99%

Battery pack recycling challenges for the year 2030: Recommended solutions based on intelligent robotics for safe and efficient disassembly, residual energy detection, and secondary utilization

et al. 2020

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With the increasing use of batteries, battery recycling would become a considerable problem in the next decade. However, the current recycling technologies are still on the stage of research and development. A significant challenge in the traditional recycling method is that the recovery procedure relies heavily on manual work. Therefore, it is necessary to develop an intelligent, automatic or semi-automatic framework for rapid disassembly and efficient recovery of retired batteries. In this study, the key research problems during the battery recycling process were identified first. The main recycling process was divided into three parts: automatic disassemble process, residual energy detection, and second utilization as well as chemical recycling. Based on the above research gaps, a qualitative framework of UR5 robots for safe and fast battery recycling, residual energy detection, and secondary utilization of retired batteries was proposed. The framework includes a battery position and shape measurement system based on machine vision, an automatic battery removal system based on UR5 industrial robot, a battery residual energy detection, and classification system. Furthermore, a real case study of battery pack recycling was carried out based on manual work and automatic robot work. The results show that the proposed recycling framework can work efficiently compared with the traditional recycling method. Moreover, the future perspectives of battery recycling are summarized. K E Y W O R D S conservation of materials, disassembly, efficient recycling, environmental benefits, intelligent robotics, recovery 1 | INTRODUCTION At present, China ranks among the world's largest producers and consumers of lithium batteries. The annual battery consumption reaches 8 billion. 1 If the waste lithium batteries are not processed and recycled systematically, it will seriously waste resources, pollute the environment, and endanger human health. It can be seen that the recycling and reuse of waste batteries has a broad market. Due to the accelerated replacement of consumer

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“…The proposed parameter optimization problem is strongly nonlinear, enabling it difficult to find the optimal parameters through numeric methods. To solve it, the SA algorithm is implemented to find them effectively [38]. The SA algorithm chooses the six parameters as the control target…”

Section: State Of Health Diagnosismentioning

confidence: 99%

Online diagnosis of state of health for lithium-ion batteries based on short-term charging profiles

Shu

Zhang

et al. 2020

Journal of Power Sources

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In this study, a machine learning method is proposed for online diagnosis of battery state of health.A prediction model for future voltage profiles is established based on the extreme learning machine algorithm with the short-term charging data. A fixed size least squares-based support vector machine with a mixed kernel function is employed to learn the dependency of state of health on feature variables generated from the charging voltage profile without preprocessing data. The simulated annealing method is employed to search and optimize the key parameters of the fixed size least squares support vector machine and the mixed kernel function. By this manner, the proposed algorithm requires only partial random and discontinuous charging data, enabling practical online diagnosis of state of health. The model training and experimental validation are conducted with different kernel functions, and the influence of voltage range and noise are also investigated.The results indicate that the proposed method can not only maintain the state of health estimation error within 2%, but also improve robustness and reliability.

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An integrated framework for minimization of inter lithium‐ion cell temperature differences and the total volume of the cell of battery pack for electric vehicles

Cited by 9 publications

References 30 publications

Boosted Charge Transfer in Twinborn α-(Mn₂O₃–MnO₂) Heterostructures: Toward High-Rate and Ultralong-Life Zinc-Ion Batteries

Boosted Charge Transfer in Twinborn α-(Mn₂O₃–MnO₂) Heterostructures: Toward High-Rate and Ultralong-Life Zinc-Ion Batteries

Battery pack recycling challenges for the year 2030: Recommended solutions based on intelligent robotics for safe and efficient disassembly, residual energy detection, and secondary utilization

Online diagnosis of state of health for lithium-ion batteries based on short-term charging profiles

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An integrated framework for minimization of inter lithium‐ion cell temperature differences and the total volume of the cell of battery pack for electric vehicles

Cited by 9 publications

References 30 publications

Boosted Charge Transfer in Twinborn α-(Mn2O3–MnO2) Heterostructures: Toward High-Rate and Ultralong-Life Zinc-Ion Batteries

Boosted Charge Transfer in Twinborn α-(Mn2O3–MnO2) Heterostructures: Toward High-Rate and Ultralong-Life Zinc-Ion Batteries

Battery pack recycling challenges for the year 2030: Recommended solutions based on intelligent robotics for safe and efficient disassembly, residual energy detection, and secondary utilization

Online diagnosis of state of health for lithium-ion batteries based on short-term charging profiles

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Product

Resources

About

Boosted Charge Transfer in Twinborn α-(Mn₂O₃–MnO₂) Heterostructures: Toward High-Rate and Ultralong-Life Zinc-Ion Batteries

Boosted Charge Transfer in Twinborn α-(Mn₂O₃–MnO₂) Heterostructures: Toward High-Rate and Ultralong-Life Zinc-Ion Batteries