In-Life Range Modularity for Electric Vehicles: The Environmental Impact of a Range-Extender Trailer System

Hooftman, Nils Stephan; Messagie, Maarten; Joint, Frédéric; Segard, Jean-Baptiste; Coosemans, Thierry

doi:10.3390/app8071016

Cited by 21 publications

(20 citation statements)

References 33 publications

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“…Regarding the operation phase, all of the LCA studies on traction Li-ion batteries examined factored in that the battery pack would need to be replaced after 150,000–160,000 km based on automotive industry warranties (Ahmadi et al., 2017; Faria et al., 2014; Hawkins et al., 2013; Richa et al., 2015) or on the authors’ assumption (Girardi et al., 2015; Hooftman et al., 2018; Szczechowicz et al., 2012; Wu et al., 2018; Zackrisson et al., 2010). There is no evidence in the LCA studies of experimental data about battery lifetime.…”

Section: Lca Of Li-ion Traction Batteries: State Of the Artmentioning

confidence: 99%

Energy and environmental assessment of a traction lithium-ion battery pack for plug-in hybrid electric vehicles

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Bobba

Ardente

et al. 2019

Journal of Cleaner Production

204

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Traction batteries are a key factor in the environmental sustainability of electric mobility and, therefore, it is necessary to evaluate their environmental performance to allow a comprehensive sustainability assessment of electric mobility. This article presents an environmental assessment of a lithium-ion traction battery for plug-in hybrid electric vehicles, characterized by a composite cathode material of lithium manganese oxide (LiMn 2 O 4 ) and lithium nickel manganese cobalt oxide Li(Ni x Co y Mn 1-x-y )O 2 . Composite cathode material is an emerging technology that promises to combine the merits of several active materials into a hybrid electrode to optimize performance and reduce costs. In this study, the environmental assessment of one battery pack (with a nominal capacity of 11.4 kWh able to be used for about 140,000 km of driving) is carried out by using the Life Cycle Assessment methodology consistent with ISO 14040. The system boundaries are the battery production, the operation phase and recycling at the end of life, including the recovery of various material fractions. The composite cathode technology examined besides a good compromise between the higher and the lower performance of NMC and LMO cathodes, can present good environmental performances. The results of the analysis show that the manufacturing phase is relevant to all assessed impact categories (contribution higher than 60%). With regard to electricity losses due to battery efficiency and battery transport, the contribution to the use phase impact of battery efficiency is larger than that of battery transport. Recycling the battery pack contributes less than 11% to all of the assessed impact categories, with the exception of freshwater ecotoxicity (60% of the life cycle impact). The environmental credits related to the recovery of valuable materials (e.g. cobalt and nickel sulphates) and other metal fractions (e.g. aluminium and steel) are particularly relevant to impact categories such as marine eutrophication, human toxicity and abiotic resource depletion. The main innovations of this article are that (1) it presents the first bill of materials of a lithium-ion battery cell for plug-in hybrid electric vehicles with a composite cathode active material; (2) it describes one of the first applications of the life cycle assessment to a lithium-ion battery pack for plug-in hybrid electric vehicles with a composite cathode active material with the aim of identifying the “hot spots” of this technology and providing useful information to battery manufacturers on potentially improving its environmental sustainability; (3) it evaluates the impacts associated with the use phase based on primary data about the battery pack's lifetime, in terms of kilometres driven; and (4) it models the end-of-life phase of the battery components through processes specifically created for or adapted to...

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Section: Lca Of Li-ion Traction Batteries: State Of the Artmentioning

confidence: 99%

Energy and environmental assessment of a traction lithium-ion battery pack for plug-in hybrid electric vehicles

Cusenza

Bobba

Ardente

et al. 2019

Journal of Cleaner Production

204

View full text Add to dashboard Cite

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“…The electrification of luxury class or sport utility vehicles (SUVs) has been criticized because of huge batteries needed and corresponding weight increases [20,21]. Ellingsen et al [22] investigated this size effect, concluding that smaller electric vehicles (EVs), equipped with smaller batteries, are more quickly overtaking combustion engine cars with respect to the carbon footprint (also see [23]). The question arises whether these problems have been adequately addressed in detail by life cycle assessment so far-almost all LCA reports quantifying the impacts of electric vehicles are based on standardized inventories and type approval registration data (reviewed in reference [24]).…”

Section: Introductionmentioning

confidence: 99%

Sensitivity Analysis in the Life-Cycle Assessment of Electric vs. Combustion Engine Cars under Approximate Real-World Conditions

2020

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This study compares the environmental impacts of petrol, diesel, natural gas, and electric vehicles using a process-based attributional life cycle assessment (LCA) and the ReCiPe characterization method that captures 18 impact categories and the single score endpoints. Unlike common practice, we derive the cradle-to-grave inventories from an originally combustion engine VW Caddy that was disassembled and electrified in our laboratory, and its energy consumption was measured on the road. Ecoivent 2.2 and 3.0 emission inventories were contrasted exhibiting basically insignificant impact deviations. Ecoinvent 3.0 emission inventory for the diesel car was additionally updated with recent real-world close emission values and revealed strong increases over four midpoint impact categories, when matched with the standard Ecoinvent 3.0 emission inventory. Producing batteries with photovoltaic electricity instead of Chinese coal-based electricity decreases climate impacts of battery production by 69%. Break-even mileages for the electric VW Caddy to pass the combustion engine models under various conditions in terms of climate change impact ranged from 17,000 to 310,000 km. Break-even mileages, when contrasting the VW Caddy and a mini car (SMART), which was as well electrified, did not show systematic differences. Also, CO 2 -eq emissions in terms of passenger kilometers travelled (54-158 g CO 2 -eq/PKT) are fairly similar based on 1 person travelling in the mini car and 1.57 persons in the mid-sized car (VW Caddy). Additionally, under optimized conditions (battery production and use phase utilizing renewable electricity), the two electric cars can compete well in terms of CO 2 -eq emissions per passenger kilometer with other traffic modes (diesel bus, coach, trains) over lifetime. Only electric buses were found to have lower life cycle carbon emissions (27-52 g CO 2 -eq/PKT) than the two electric passenger cars.

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“…Concerning human toxicity, the impact is proportional to battery size, although the battery trailer performs better than the 90 kWh EV due to its occasional application rather than carrying along such high capacity all the time. For climate change, we see a clear advantage of both the petrol and the battery trailer, with reductions ranging from one-third to nearly 60%, respectively [14].…”

Section: Environmental Assessments Of Electrified Vehiclesmentioning

confidence: 95%

“…Nils Hooftman et al [14] compare the environmental impact of the combination of a 40 kWh EV and a trailer options with a range of conventional cars and EVs, differentiated per battery capacity. In this paper, they distinguish plug-in hybrid electric vehicles (PHEVs), electric vehicles (EVs) with a modest battery capacity of 40 kWh, and long-range EVs with 90 kWh installed.…”

Section: Environmental Assessments Of Electrified Vehiclesmentioning

confidence: 99%

Special Issue “Plug-In Hybrid Electric Vehicle (PHEV)”

Mierlo

2019

Applied Sciences

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Climate change, urban air quality, and dependency on crude oil are important societal challenges. In the transportation sector especially, clean and energy-efficient technologies must be developed. Electric vehicles (EVs) and plug-in hybrid electric vehicles (PHEVs) have gained a growing interest in the vehicle industry. Nowadays, the commercialization of EVs and PHEVs has been possible in different applications (i.e., light duty, medium duty, and heavy duty vehicles) thanks to the advances in energy-storage systems, power electronics converters (including DC/DC converters, DC/AC inverters, and battery charging systems), electric machines, and energy efficient power flow control strategies. This Special Issue is focused on the recent advances in electric vehicles and (plug-in) hybrid vehicles that address the new powertrain developments and go beyond the state-of-the-art (SOTA).

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In-Life Range Modularity for Electric Vehicles: The Environmental Impact of a Range-Extender Trailer System

Cited by 21 publications

References 33 publications

Energy and environmental assessment of a traction lithium-ion battery pack for plug-in hybrid electric vehicles

Energy and environmental assessment of a traction lithium-ion battery pack for plug-in hybrid electric vehicles

Sensitivity Analysis in the Life-Cycle Assessment of Electric vs. Combustion Engine Cars under Approximate Real-World Conditions

Special Issue “Plug-In Hybrid Electric Vehicle (PHEV)”

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