Design and On-Field Validation of an Embedded System for Monitoring Second-Life Electric Vehicle Lithium-Ion Batteries

Castillo-Martínez, Diego Hilario; Rodríguez-Rodríguez, Adolfo Josué; Soto, Adrian; Berrueta, Alberto; Vargas-Requena, David Tomás; Matı́as, Ignacio R.; Sanchis, Pablo; Rodríguez-Rodríguez, Wenceslao Eduardo

doi:10.3390/s22176376

Cited by 8 publications

(8 citation statements)

References 27 publications

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“…The battery-management system is the central controller of the second-life battery packs installed in the stationary energy-storage system [119]. In each battery module, there some sensors installed to measure the cells' temperature and voltage and to estimate the current applied under various operating conditions [120]. The battery-management system will use the measured sensor data from each module to estimate the state of charge and state of health of the battery cells, modules, and packs during operation using characterized ECM and SOH estimation algorithms that are programmed into the microcontroller board (Figure 23) [120].…”

Section: Battery-management Strategiesmentioning

confidence: 99%

“…In each battery module, there some sensors installed to measure the cells' temperature and voltage and to estimate the current applied under various operating conditions [120]. The battery-management system will use the measured sensor data from each module to estimate the state of charge and state of health of the battery cells, modules, and packs during operation using characterized ECM and SOH estimation algorithms that are programmed into the microcontroller board (Figure 23) [120]. The state-of-health estimation algorithm accuracy of the second-life battery packs plays a key role as it enables the BMS to calculate the probability of reaching the thermal runaway point in each battery module inside the pack [121].…”

Section: Battery-management Strategiesmentioning

confidence: 99%

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A Review of the Technical Challenges and Solutions in Maximising the Potential Use of Second Life Batteries from Electric Vehicles

Salek,

Resalati,

Babaie

et al. 2024

Batteries

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The increasing number of electric vehicles (EVs) on the roads has led to a rise in the number of batteries reaching the end of their first life. Such batteries, however, still have a capacity of 75–80% remaining, creating an opportunity for a second life in less power-intensive applications. Utilising these second-life batteries (SLBs) requires specific preparation, including grading the batteries based on their State of Health (SoH); repackaging, considering the end-use requirements; and the development of an accurate battery-management system (BMS) based on validated theoretical models. In this paper, we conduct a technical review of mathematical modelling and experimental analyses of SLBs to address existing challenges in BMS development. Our review reveals that most of the recent research focuses on environmental and economic aspects rather than technical challenges. The review suggests the use of equivalent-circuit models with 2RCs and 3RCs, which exhibit good accuracy for estimating the performance of lithium-ion batteries during their second life. Furthermore, electrochemical impedance spectroscopy (EIS) tests provide valuable information about the SLBs’ degradation history and conditions. For addressing calendar-ageing mechanisms, electrochemical models are suggested over empirical models due to their effectiveness and efficiency. Additionally, generating cycle-ageing test profiles based on real application scenarios using synthetic load data is recommended for reliable predictions. Artificial intelligence algorithms show promise in predicting SLB cycle-ageing fading parameters, offering significant time-saving benefits for lab testing. Our study emphasises the importance of focusing on technical challenges to facilitate the effective utilisation of SLBs in stationary applications, such as building energy-storage systems and EV charging stations.

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Section: Battery-management Strategiesmentioning

confidence: 99%

Section: Battery-management Strategiesmentioning

confidence: 99%

A Review of the Technical Challenges and Solutions in Maximising the Potential Use of Second Life Batteries from Electric Vehicles

Salek,

Resalati,

Babaie

et al. 2024

Batteries

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“…Energies 2023, 16, 953 5 of 14 A three-stage assessment method was introduced by Castillo-Martínez et al [22]. The first step is the visual inspection, which reveals cells or modules with apparent physical damage, which can be immediately rejected.…”

Section: Second-life Batteries: Recycling and Reuse Processmentioning

confidence: 99%

Second Life of Lithium-Ion Batteries of Electric Vehicles: A Short Review and Perspectives

et al. 2023

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Technological advancement in storage systems has currently stimulated their use in miscellaneous applications. The devices have gained prominence due to their increased performance and efficiency, together with the recent global appeal for reducing the environmental impacts caused by generating power or by combustion vehicles. Many technologies have been developed to allow these devices to be reused or recycled. In this sense, the use of lithium-ion batteries, especially in electric vehicles, has been the central investigative theme. However, a drawback of this process is discarding used batteries. This work provides a short review of the techniques used for the second-life batteries of electric vehicles and presents the current positioning of the field, the steps involved in the process of reuse and a discussion on important references. In conclusion, some directions and perspectives of the field are shown.

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“…However, according to the current state of technological development, most operating systems on the market are equipped with large-capacity storage devices, and large-capacity storage devices can promote the increase in computing speed to a certain extent. Therefore, when comparing embedded devices with other operating systems on the market, the processing speed of the embedded operating systems is much lower than other large operating systems [ 15 , 16 ]. In the following description in this article, nonembedded general-purpose computer devices are collectively referred to as general-purpose devices.…”

Section: Related Workmentioning

confidence: 99%

IoT Network for International Trade Cold Chain Logistics Tracking Based on Kalman Algorithm

Zhang

Wei

2022

Computational Intelligence and Neuroscience

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The application of Internet of Things technology in cold chain transportation can greatly strengthen the monitoring of all aspects of cold chain logistics, so as to promote the progress of cold chain logistics industry. In order to study this aspect, this paper chooses the key link of the Internet of Things as a breakthrough. By analyzing various aspects of the transportation process, an Internet of Things middleware framework serving cold chain transportation tracking is designed. The main products of logistics cold chain transportation are fresh agricultural products, so in order to further make the research fit the actual situation, this paper collects the logistics data and information of agricultural products through investigation and combines the core technology of agricultural products logistics with the Internet and the key technology of cold chain transportation to process the obtained information. The analytic hierarchy process and fuzzy comprehensive evaluation method are used in this process. The processing results prove the validity and rationality of the established index system. The purpose of developing the international trade management system is to enable the company to optimize its international trade management process, reduce some tedious and inconvenient manual operations, make the recording and statistics of international trade information very simple, improve work efficiency, and satisfy the information needs of various departments to enable enterprises to minimize costs, thereby enabling enterprises to obtain better economic benefits.

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Design and On-Field Validation of an Embedded System for Monitoring Second-Life Electric Vehicle Lithium-Ion Batteries

Cited by 8 publications

References 27 publications

A Review of the Technical Challenges and Solutions in Maximising the Potential Use of Second Life Batteries from Electric Vehicles

A Review of the Technical Challenges and Solutions in Maximising the Potential Use of Second Life Batteries from Electric Vehicles

Second Life of Lithium-Ion Batteries of Electric Vehicles: A Short Review and Perspectives

IoT Network for International Trade Cold Chain Logistics Tracking Based on Kalman Algorithm

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