Effects of Electric Vehicle Fast Charging on Battery Life and Vehicle Performance

Shirk, Matthew; Wishart, Jeffrey

doi:10.4271/2015-01-1190

Cited by 43 publications

(30 citation statements)

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“…An experimental study in Phoenix, Arizona found slightly increased rates of SoH decline in two 24 kWh Leafs that were always rapid charged compared to two others that were slow charged 320 (Shirk, 2015). The sample size was small, the experiment lasted only a year and a half, and the vehicles were driven extraordinarily long distances in much hotter conditions than prevail in New Zealand.…”

mentioning

confidence: 99%

Accelerated Reported Battery Capacity Loss in 30 kWh Variants of the Nissan Leaf

Myall¹,

Ivanov²,

Larason³

et al. 2018

Preprint

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Analysis of 1,382 measures of battery State of Health (SoH) from 283 Nissan Leafs ("Leaf/s"), manufactured between 2011 and 2017, has detected a faster rate of decline in this measure of energy-holding capacity for 30 kWh variants. At two years of age, the mean rate of decline of SoH of 30 kWh Leafs was 9.9% per annum (95% uncertainty interval of 8.7% to 11.1%; 25 n=82). This was around three times the rate of decline of 24 kWh Leafs which at two years averaged 3.1% per annum (95% uncertainty interval of 2.9% to 3.3%; n=201). For both variants there was evidence for an increasing rate of decline as they aged, although this was much more pronounced in the 30 kWh Leafs. Higher use of rapid DC charging was associated with a small decrease in SoH. Additionally, while 24 kWh cars with greater distances travelled showed a higher 30 SoH, in 30 kWh cars there was a reduction in SoH observed in cars that had travelled further. The 30 kWh Leafs sourced from United Kingdom showed slower initial decline than those from Japan, but the rate of decline was similar at two years of age. Improvements in the battery health diagnostics, continuous monitoring of battery temperatures and state of charge, and verification of a fundamental model of battery health are needed before causes and remedies for the observed 35 decline can be pinpointed. If the high rate of decline in battery capacity that we observed in the first 2.3 years of a 30 kWh Leaf's lifetime were to continue, the financial and environmental benefits of this model may be significantly eroded. Despite 30 kWh Leafs accounting for only 14% of all light battery electric vehicles registered for use on New Zealand roads at the end of February 2018, there is also the potential for the relatively poor performance of this specific model to undermine electric 40 vehicle uptake more generally unless remedies can be found.

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confidence: 99%

Accelerated Reported Battery Capacity Loss in 30 kWh Variants of the Nissan Leaf

Myall¹,

Ivanov²,

Larason³

et al. 2018

Preprint

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“…A simple exemplary calculation is feasible using this formula. Assuming a typical temperature collectively taken from [20], an operating time (lifetime) of 8000 h, an activation energy for the gap filler of 0.45 eV [21], and a test temperature of 85 • C, then the average acceleration factor is 8.4 which means that the lifetime is reached within 958 h of testing time, as shown in Table 1.…”

Section: Arrhenius Modelmentioning

confidence: 99%

Methods for Durability Testing and Lifetime Estimation of Thermal Interface Materials in Batteries

Stadler

Maurer

2019

Batteries

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To ensure sufficient thermal performance within electric vehicle (EV) batteries, thermal interface materials (TIMs), such as pastes or adhesives, are widely used to fill thermally insulating voids between cells and cooling components. However, TIMs are composite materials that are subject to degradation over the battery’s lifetime. Using TIMs for battery applications is a new and emerging topic, creating the need to rapidly acquire knowledge about appropriate lifetime testing and evaluation methods, in close collaboration with the battery manufacturers. This paper reviews suitable methods for durability testing as well as basic modeling approaches which allow for the transfer of laboratory results to the longtime behavior of interface materials during a vehicle’s lifetime.

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“…Although some specific EV batteries are designed for fast charging, they will in fact degrade slightly faster when charged with DC fast charging. In a comparison of two Nissan Leafs, with one vehicle using only slow charging and the other fast charging, after 50,000 km the type of charging had only a small effect on battery capacity with a maximum amount of 5 percent additional degradation (Shirk and Wishart 2015). -Driving behavior and loading.…”

Section: Battery Performance and Life Spanmentioning

confidence: 99%

The Bhutan Electric Vehicle Initiative: Scenarios, Implications, and Economic Impact

Zhu¹,

Patella²,

Steinmetz³

et al. 2016

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Effects of Electric Vehicle Fast Charging on Battery Life and Vehicle Performance

Cited by 43 publications

References 0 publications

Accelerated Reported Battery Capacity Loss in 30 kWh Variants of the Nissan Leaf

Accelerated Reported Battery Capacity Loss in 30 kWh Variants of the Nissan Leaf

Methods for Durability Testing and Lifetime Estimation of Thermal Interface Materials in Batteries

The Bhutan Electric Vehicle Initiative: Scenarios, Implications, and Economic Impact

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