System-Level Modeling and Thermal Simulations of Large Battery Packs for Electric Trucks

Babu, Anandh Ramesh; Andrić, Jelena; Minovski, Blago; Sebben, Simone

doi:10.3390/en14164796

Cited by 11 publications

(2 citation statements)

References 26 publications

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“…Both sources of heat depend on various factors, such as temperature, state of charge, current rate, aging effect, rapid acceleration, and sustained high‐speed driving that can increase heat generation, leading to temperature rise within the battery pack. [ 1,2,42 ] Accumulated heat can degrade battery performance, shorten lifespan, and potentially result in safety hazards such as thermal runaway. [ 43 ] The total heat generation rate of an LIB can be expressed as

Q = Q_{\text{J}} &amp;#x00026;amp;amp;amp;amp;amp;amp;amp;amp;amp;plus; Q_{\text{R} }

where Q J is the Joule heat generation rate and Q R is the reaction heat generation rate.…”

Section: Factors and Challenges In Battery Thermal Management Systemmentioning

confidence: 99%

Advancements in Battery Cooling Techniques for Enhanced Performance and Safety in Electric Vehicles: A Comprehensive Review

Rallabandi,

Issac Selvaraj

2024

Energy Tech

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The automotive industry is transitioning toward electric vehicles (EVs) to control fossil fuel dependence, reduce CO2 emissions, and mitigate pollution. EVs powered by lithium‐ion batteries (LIBs) have gained significant popularity due to their low operational costs and high energy density. Despite the substantial popularity of EVs powered by LIBs, their widespread commercial deployment has been impeded by challenges associated with operating temperatures. These temperature variations can adversely affect battery performance, degradation, and safety, posing hurdles to overcome for their efficient integration into vehicles. To address these issues, the development of high‐performance effective cooling techniques is crucial in mitigating the adverse effects of surface temperatures on battery cells. This review article aims to provide a comprehensive analysis of the advancements and enhancements in battery cooling techniques and their impact on EVs. It explores various cooling and heating methods to improve the performance and lifespan of EV batteries. It delves into suitable cooling methods as effective strategies for managing high surface temperatures and enhancing thermal efficiency. The study encompasses a comprehensive analysis of different cooling system designs with innovative approaches. Furthermore, this article outlines future research directions and potential solutions for developing battery cooling systems in electric and hybrid electric vehicles.

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Q = Q_{\text{J}} &amp;#x00026;amp;amp;amp;amp;amp;amp;amp;amp;amp;plus; Q_{\text{R} }

where Q J is the Joule heat generation rate and Q R is the reaction heat generation rate.…”

Section: Factors and Challenges In Battery Thermal Management Systemmentioning

confidence: 99%

Advancements in Battery Cooling Techniques for Enhanced Performance and Safety in Electric Vehicles: A Comprehensive Review

Rallabandi,

Issac Selvaraj

2024

Energy Tech

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“…Several authors investigated thermal behavior of large battery packs suited for trucks, e.g. [13]. Furthermore, the influence of thermal encapsulation of truck batteries was investigated.…”

Section: Introductionmentioning

confidence: 99%

Innovative Thermal Management Operating Strategies for Battery-Electric Heavy-Duty Trucks

Hellmuth,

Steeb,

Pollak

et al. 2023

36th International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems (ECOS 20

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Thermal management systems of electrified vehicles especially heavy-duty trucks face multiple competing goals such as minimum energy consumption, minimum battery degradation and highest passenger comfort. The design process of a suitable thermal management system addressing these goals requires a holistic approach including the various cross couplings occurring in real world operation. Therefore, a physics-based modular full-vehicle model is introduced. The model includes an electrified drive-train, passenger cabin and thermal management system. The mechanical and electrical drive-train components, including the battery, motor and power electronics are thermally connected with each other and the cabin using various cooling circuits. A reversible heat pump and several control units are used to adjust the specific thermal requirements leading to complex interconnections and cross couplings. We estimate the performance of a heavy-duty truck on typical long-distance trips including stops based on legal regulations used for fast charging and overnight charging. While charging overnight, conservation air conditioning of the cabin is performed as efficiently as possible. For this operation, we present different strategies for battery thermal conditioning. Operating strategies for the full vehicle, especially the thermal systems in a summer and a winter scenario are proposed. Simulations of a typical deployment scenario are performed to explore the effects of different operating and control strategies for thermal management. Our virtual deployment scenarios include easy to modify driving cycles, driving time regulations, charge stops and climatic boundary conditions. For evaluation purposes we present an energyflow-diagram for the full vehicle. Based on the simulation results we recommend thermal system operating strategies in a full-vehicle context for heavy-duty truck long distance trips and charging.

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Thermal encapsulation of large battery packs for electric vehicles operating in cold climate

Babu

Minovski

Sebben

2022

Applied Thermal Engineering

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System-Level Modeling and Thermal Simulations of Large Battery Packs for Electric Trucks

Cited by 11 publications

References 26 publications

Advancements in Battery Cooling Techniques for Enhanced Performance and Safety in Electric Vehicles: A Comprehensive Review

Advancements in Battery Cooling Techniques for Enhanced Performance and Safety in Electric Vehicles: A Comprehensive Review

Innovative Thermal Management Operating Strategies for Battery-Electric Heavy-Duty Trucks

Thermal encapsulation of large battery packs for electric vehicles operating in cold climate

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