Application of Robust Design Methodology to Battery Packs for Electric Vehicles: Identification of Critical Technical Requirements for Modular Architecture

Arora, Shashank; Kapoor, Ajay; Shen, Weixiang

doi:10.3390/batteries4030030

Cited by 35 publications

(10 citation statements)

References 57 publications

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“…Therefore, from the population of 31 batteries, we tested the batteries that had similar length of raw observations (32 months) in order to verify if they represented similar kind of sample distributions. Here we made assumptions that the difference in operating temperatures or driving patterns may have significant impact on the individual battery SoH behavior [29][30]. Finally, there were 14 batteries that had 32 months of data including the battery A; the rest of the time series were shorter.…”

Section: Comparison Of 31 Battery Time Series -Resultsmentioning

confidence: 99%

A Dynamic Battery State-of-Health Forecasting Model for Electric Trucks: Li-Ion Batteries Case-Study

et al. 2020

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It is of extreme importance to monitor and manage the battery health to enhance the performance and decrease the maintenance cost of operating electric vehicles. This paper concerns the machine-learning-enabled state-of-health (SoH) prognosis for Li-ion batteries in electric trucks, where they are used as energy sources. The paper proposes methods to calculate SoH and cycle life for the battery packs. We propose autoregressive integrated modeling average (ARIMA) and supervised learning (bagging with decision tree as the base estimator; BAG) for forecasting the battery SoH in order to maximize the battery availability for forklift operations. As the use of data-driven methods for battery prognostics is increasing, we demonstrate the capabilities of ARIMA and under circumstances when there is little prior information available about the batteries. For this work, we had a unique data set of 31 lithium-ion battery packs from forklifts in commercial operations. On the one hand, results indicate that the developed ARIMA model provided relevant tools to analyze the data from several batteries. On the other hand, BAG model results suggest that the developed supervised learning model using decision trees as base estimator yields better forecast accuracy in the presence of large variation in data for one battery.

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Section: Comparison Of 31 Battery Time Series -Resultsmentioning

confidence: 99%

A Dynamic Battery State-of-Health Forecasting Model for Electric Trucks: Li-Ion Batteries Case-Study

et al. 2020

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“…The required installation space can vary between full electric vehicles and hybrid electric vehicles. Full-electric vehicles typically use the underfloor structure of the car's body between both axles, whereas hybrids use free space under the back seats or the centre tunnel [14][15][16].…”

Section: Product Structure Of Battery Systemsmentioning

confidence: 99%

Product-requirement-model to approach the identification of uncertainties in battery systems development

Heimes

Kampker

Haunreiter

et al. 2020

Int J Interact Des Manuf

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Electric mobility is on the verge of becoming a mass market. Major automotive OEMs have initiated programs to electrify their product portfolio. This transition poses new challenges and requires new innovative concepts in automotive development processes, especially for battery systems as the key component within electric powertrains. Battery system costs account for up to 40% of the electric vehicle’s total costs. Additionally, development cycles of battery systems for automotive applications are characterized by long development periods. Hence, the initiatives to advance electrification result in numerous development projects affiliated with significant development expenses. Battery systems can be referred to as mechatronic and electrochemical systems. They require a complex interaction of diverse scientific and engineering disciplines. Fast innovation cycles have effects regarding product requirements and assumptions towards their allocation. Hereby, uncertainties can lead to risks within development projects, especially in terms of time and costs. In current development processes, necessary changes are only dealt with reactively, causing unplanned additional expenses and delays. Thus, there is need for handling potential changes proactively, i.e. managing uncertainties leading to those changes as early as possible. New methods are necessary to identify and handle uncertainties of complex product systems within requirements engineering. An approach towards comprehensive uncertainty management is taken within this publication.

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“…Because the battery pack is the ultimate power source for EV, the R&D focus on efficient design and structure of packs/modules is also increasing besides the R&D on battery materials and cell development. [42][43][44] The design of the battery pack depends significantly on the dimensions of the products, the interconnecting circuits, safety, and temperature control aspects. The slimness of a pack can determine if the design of an EV can be more or less stylish.…”

Section: Function and Control Of Ev Batteries (Vehicle-level Summary)mentioning

confidence: 99%

Operation, Manufacturing, and Supply Chain of Lithium-ion Batteries for Electric Vehicles

Belharouak

Nanda

Self

et al. 2020

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Application of Robust Design Methodology to Battery Packs for Electric Vehicles: Identification of Critical Technical Requirements for Modular Architecture

Cited by 35 publications

References 57 publications

A Dynamic Battery State-of-Health Forecasting Model for Electric Trucks: Li-Ion Batteries Case-Study

A Dynamic Battery State-of-Health Forecasting Model for Electric Trucks: Li-Ion Batteries Case-Study

Product-requirement-model to approach the identification of uncertainties in battery systems development

Operation, Manufacturing, and Supply Chain of Lithium-ion Batteries for Electric Vehicles

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