Phase Change Materials Application in Battery Thermal Management System: A Review

Liu, Changcheng; Xu, Dengji; Weng, Jingwen; Zhou, Shujia; Li, Wenjuan; Wan, Yongqing; Jiang, Shuaijun; Zhou, Dechuang; Wang, Jian; Huang, Que

doi:10.3390/ma13204622

Cited by 166 publications

(74 citation statements)

References 141 publications

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“…Such materials rely on the large latent heat of vaporization that occurs during a phase change (for example, when a wax melts to become a liquid). Further information on work in this area may be found in references [38][39][40].…”

Section: Thermal Fluids For Control Of Battery Temperaturementioning

confidence: 99%

Energy Efficiency, Emissions, Tribological Challenges and Fluid Requirements of Electrified Passenger Car Vehicles

Taylor

2021

Lubricants

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The motivations for the move to electrified vehicles are discussed with reference to their improved energy efficiency, their potential for lower CO2 emissions (if the electricity system is decarbonized), their lower (or zero) NOx/particulate matter (PM) tailpipe emissions, and the lower overall costs for owners. Some of the assumptions made in life-cycle CO2 emissions calculations are discussed and the effect of these assumptions on the CO2 benefits of electric vehicles are made clear. A number of new tribological challenges have emerged, particularly for hybrid vehicles that have both a conventional internal combustion engine and a battery, such as the need to protect against the much greater number of stop-starts that the engine will have during its lifetime. In addition, new lubricants are required for electric vehicle transmissions systems. Although full battery electric vehicles (BEVs) will not require engine oils (as there is no engine), they will require a system to cool the batteries—alternative cooling systems are discussed, and where these are fluid-based, the specific fluid requirements are outlined.

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Section: Thermal Fluids For Control Of Battery Temperaturementioning

confidence: 99%

Energy Efficiency, Emissions, Tribological Challenges and Fluid Requirements of Electrified Passenger Car Vehicles

Taylor

2021

Lubricants

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show abstract

Section: Thermal Fluids For Control Of Battery Temperaturementioning

confidence: 99%

Energy Efficiency, Emissions, Tribological Challenges and Fluid Requirements of Electrified Passenger Car Vehicles

Taylor¹

2021

Preprint

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The motivations for the move to electrified vehicles are discussed with reference to their improved energy efficiency, their potential for lower CO2 emissions (if the electricity system is decarbonized), their lower (or zero) NOx/particulate matter (PM) tailpipe emissions, and the lower overall costs for owners. Some of the assumptions made in life-cycle CO2 emissions calculations are discussed and the effect of these assumptions on the CO2 benefits of electric vehicles are made clear. A number of new tribological challenges have emerged, particularly for hybrid vehicles that have both a conventional internal combustion engine and a battery, such as the need to protect against the much greater number of stop-starts that the engine will have during its lifetime. In addition, new lubricants are required for electric vehicle transmissions systems. Although full battery electric vehicles (BEVs) will not require engine oils (as there is no engine) they will require a system to cool the batteries – alternative cooling systems are discussed, and where these are fluid based, the specific fluid requirements are outlined.

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“…Energy shortage and environmental problems have led to a positive search in energy consumption and conservation. [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20] Among multitudinous types of storage and conversion technologies, rechargeable Li-O 2 batteries [21][22][23][24] (LOBs) are regarded as the potential candidates for energy storage owing to their ultra-high theoretical energy density reaching 3600 W h Kg −1 , originating from the process of oxygen being reduced to form lithium peroxide (2Li + O 2 ↔ Li 2 O 2 , 2.96 V vs. Li/Li + ), which is nearly ten times higher than commercialized lithium-ion batteries. [25][26][27] However, in comparison with an ideal reaction process, complex reaction mechanisms and possible by-products exist resulting in challenges [28][29][30] including inferior specific capacity, low round trip energy efficiency, poor cycle performance, which hinder its further development.…”

Section: Introductionmentioning

confidence: 99%

Co₃O₄ nanoparticle-dotted hierarchical-assembled carbon nanosheet framework catalysts with the formation/decomposition mechanisms of Li₂O₂ for smart lithium–oxygen batteries

Zhai

Yang

Xie

et al. 2022

Inorg. Chem. Front.

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Phase Change Materials Application in Battery Thermal Management System: A Review

Cited by 166 publications

References 141 publications

Energy Efficiency, Emissions, Tribological Challenges and Fluid Requirements of Electrified Passenger Car Vehicles

Energy Efficiency, Emissions, Tribological Challenges and Fluid Requirements of Electrified Passenger Car Vehicles

Energy Efficiency, Emissions, Tribological Challenges and Fluid Requirements of Electrified Passenger Car Vehicles

Co₃O₄ nanoparticle-dotted hierarchical-assembled carbon nanosheet framework catalysts with the formation/decomposition mechanisms of Li₂O₂ for smart lithium–oxygen batteries

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Phase Change Materials Application in Battery Thermal Management System: A Review

Cited by 166 publications

References 141 publications

Energy Efficiency, Emissions, Tribological Challenges and Fluid Requirements of Electrified Passenger Car Vehicles

Energy Efficiency, Emissions, Tribological Challenges and Fluid Requirements of Electrified Passenger Car Vehicles

Energy Efficiency, Emissions, Tribological Challenges and Fluid Requirements of Electrified Passenger Car Vehicles

Co3O4 nanoparticle-dotted hierarchical-assembled carbon nanosheet framework catalysts with the formation/decomposition mechanisms of Li2O2 for smart lithium–oxygen batteries

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About

Co₃O₄ nanoparticle-dotted hierarchical-assembled carbon nanosheet framework catalysts with the formation/decomposition mechanisms of Li₂O₂ for smart lithium–oxygen batteries