A Review on Battery Market Trends, Second-Life Reuse, and Recycling

Zhao, Yanyan; Pohl, Oliver; Bhatt, Anand I.; Collis, Gavin E.; Mahon, Peter J.; Rüther, Thomas; Hollenkamp, Anthony F.

doi:10.3390/suschem2010011

Cited by 250 publications

(177 citation statements)

References 66 publications

(141 reference statements)

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“…The slight increase in the Cd:Zn ratio post-2011 is coincident with annual increase in Te production (Figure 2B), likely a result of thin-film CdTe PV manufacturing. However, the future demand for Cd remains uncertain as its primary use is in the production of NiCd batteries, which are being phased out as a result of the negative environmental impact of Cd, with replacements by lithium-ion and nickel-metal hydride batteries (USGS, 2021) leading to a decrease in sales of NiCd batteries at a rate of 6% per year between 2002 and 2012 (Zhao et al, 2021). This may lead to a situation, where Cd could be stockpiled by smelters and refiners without a market for this metal, creating issues over safe storage and disposal rather than any issues over the security of supply of this metal.…”

Section: Ll Open Accessmentioning

confidence: 99%

“…The current short-term apparent improvement in Cd recovery could be the result of sold stockpiled Cd intermediates or added Cd supply from recycling end-of-life NiCd batteries to meet elevated demand for CdTe solar PV production, although this remains uncertain. Equally, the fact that NiCd batteries are being phased out (Zhao et al, 2021) barring specialty uses for these batteries means that this recycling source and demand for Cd is likely to further diminish over time.…”

Section: Ll Open Accessmentioning

confidence: 99%

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Barriers to and uncertainties in understanding and quantifying global critical mineral and element supply

McNulty

Jowitt

2021

iScience

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The critical minerals and elements are natural substances that are essential to modern life but have insecure supply. This lack of a secure supply clashes with the increasing importance of these elements, especially given their use in technologies needed to reduce global CO 2 emissions and mitigate against anthropogenic climate change. In this contribution we review the by-product nature of the critical minerals and elements and the inherant uncertainties in reported critical mineral and element annual production as well as the relationships between these commodities and main-product metals and associated concentrates. We explore the geological and geographical barriers to critical mineral and element supplies, as well as how the lack of available data and the uncertainties in the data that are available hinder our ability to estimate global resources with confidence.

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Section: Ll Open Accessmentioning

confidence: 99%

Section: Ll Open Accessmentioning

confidence: 99%

Barriers to and uncertainties in understanding and quantifying global critical mineral and element supply

McNulty

Jowitt

2021

iScience

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“…According to the average speed assumed in Table 2 and the approximate energy consumption rate presented in [23], the traveling consumption is reflected in the SOC level reduction during the traveling time, as shown in Figure 9. The battery degradation cost of the MESS's battery is calculated considering a capital cost of energy capacity of $271/kWh, power conversion system cost of $288/kW (taken from [24]), an O&M cost of 0.03 cents/kWh [24], and a second-life battery selling price of $50/kWh [25]. This results in a charge/discharge cost of Finally, Figure 9 represents the state-of-charge (SOC) of the battery, noting that at the end of the day, 20% of the battery is maintained, which achieves the MDOD limit.…”

Section: Case Study-2mentioning

confidence: 99%

A Mobile Energy Storage Unit Serving Multiple EV Charging Stations

et al. 2021

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Due to the rapid increase in electric vehicles (EVs) globally, new technologies have emerged in recent years to meet the excess demand imposed on the power systems by EV charging. Among these technologies, a mobile energy storage system (MESS), which is a transportable storage system that provides various utility services, was used in this study to support several charging stations, in addition to supplying power to the grid during overload and on-peak hours. Thus, this paper proposes a new day-ahead optimal operation of a single MESS unit that serves several charging stations that share the same geographical area. The operational problem is formulated as a mixed-integer non-linear programming (MINLP), where the objective is to minimize the total operating cost of the parking lots (PLs). Two different case studies are simulated to highlight the effectiveness of the proposed system compared to the current approach.

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“…Separating batteries according to their chemistry for use in second-life applications is a problem we face. Considering the environmental effects in addition to the limited reserves of the rare earth elements and lithium used in batteries; it is also a fact that batteries that have reached the end of their useful life will be added to the waste stream with other types of batteries that are currently collected for recycling 39 . Second-life battery capacity is projected to exceed 275 GWh per year by 2030 40 .…”

Section: Introductionmentioning

confidence: 99%

“…However, there are many technical, economic and regulatory challenges that can complicate this. In the recycling process and in the sale of recycled products, it is required to classify and separate batteries according to their chemical composition 39 . The difficulty in determining the chemistry of the battery is due to the lack of proper labelling, standard design or clear marking on the package 41 .…”

Section: Introductionmentioning

confidence: 99%

Novel Approach for Battery Type Determination: A Mere Electrical Alternative

Dikmen¹,

Karadağ²

2021

Preprint

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Today, the storage of electrical energy is one of the most important technical challenges. The increasing number of high capacity, high-power applications, especially electric vehicles and grid energy storage, points to the fact that we will be faced with a large amount of batteries that will need to be recycled and separated in the near future. An alternative method to the currently used methods for separating these batteries according to their chemistry is discussed in this study. This method can be applied even on integrated circuits due to its ease of implementation and low operational cost. In this respect, it is also possible to use it in multi-chemistry battery management systems to detect the chemistry of the connected battery. For the implementation of the method, the batteries are connected to two different loads alternately. In this way, current and voltage values are measured for two different loads without allowing the battery to relax. The obtained data is pre-processed with a separation function developed based on statistical significance. In machine learning algorithms, artificial neural network and decision tree algorithms are trained with processed data and used to determine battery chemistry with 100% accuracy. The efficiency and ease of implementation of the decision tree algorithm in such a categorization method are presented comparatively.

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A Review on Battery Market Trends, Second-Life Reuse, and Recycling

Cited by 250 publications

References 66 publications

Barriers to and uncertainties in understanding and quantifying global critical mineral and element supply

Barriers to and uncertainties in understanding and quantifying global critical mineral and element supply

A Mobile Energy Storage Unit Serving Multiple EV Charging Stations

Novel Approach for Battery Type Determination: A Mere Electrical Alternative

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