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

Salek, Farhad; Resalati, Shahaboddin; Babaie, Meisam; Henshall, Paul; Morrey, Denise; Yao, Lei

doi:10.3390/batteries10030079

Cited by 6 publications

(3 citation statements)

References 123 publications

(187 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Various battery types are used in EVs, but the most promising, and currently the most common type of energy storage, is the lithium-ion (Li-ion) battery [24,25]. While Li-ion batteries have a high energy density, their power density is not high enough [26].…”

Section: Introductionmentioning

confidence: 99%

Fuzzy Logic-Based Energy Management System for Regenerative Braking of Electric Vehicles with Hybrid Energy Storage System

Şen,

Özcan,

Eker

2024

Applied Sciences

View full text Add to dashboard Cite

Electric vehicles (EVs), which are environmentally friendly, have been used to minimize the global warming caused by fossil fuels used in vehicles and increasing fuel prices due to the decrease in fossil resources. Considering that the energy used in EVs is obtained from fossil resources, it is also important to store and use energy efficiently in EVs. In this context, recovery from a regenerative braking system plays an important role in EV energy efficiency. This paper presents a fuzzy logic-based hybrid storage technique consisting of a supercapacitor (SC) and battery for efficient and safe storage of a regenerative braking system. First, the constraints of the battery to be used in the EV for fuzzy logic control are identified. Then, the fuzzy logic system is created and tested in the ADVISOR and Siemens Simcenter Flomaster programs in the New European Driving Cycle (NEDC) driving cycle. A SC was selected for primary storage to prevent the battery from being continuously charged from regenerative braking, thus reducing its lifetime. In cases where the vehicle consumes more energy than the average energy consumption, energy consumption from the battery is reduced by using the energy stored in the SC, and the SC energy is discharged, making preparations for the energy that will come from the next regenerative braking. Thus, the high current values transferred to the battery during regenerative braking are effectively limited by the SC. In this study, the current values on the battery in the EV with a hybrid storage system decreased by 29.1% in the ADVISOR program and 28.7% in the Simcenter Flomaster program. In addition, the battery generated 46.84% less heat in the hybrid storage system. Thus, the heating and capacity losses caused by this current on the battery were minimized. The presented method provides more efficient energy management for EVs and plays an important role in maintaining battery health.

show abstract

Section: Introductionmentioning

confidence: 99%

Fuzzy Logic-Based Energy Management System for Regenerative Braking of Electric Vehicles with Hybrid Energy Storage System

Şen,

Özcan,

Eker

2024

Applied Sciences

View full text Add to dashboard Cite

show abstract

“…These methods are sensitive to measurement noise and operating temperature, and require low current rates, limiting their applications [24]. Model-based methods use equivalent circuit models (ECM) or electrochemical models (EM) combined with advanced filter techniques like the Kalman filter (KF) or particle filter (PF) to calculate the battery degradation parameters for estimating the SoH [25]. Although these models can accurately reflect the dynamic characteristics of a battery, the complex internal principles and working environment make it challenging to establish a suitable battery model.…”

Section: Introductionmentioning

confidence: 99%

State of Health Prediction of Electric Vehicles’ Retired Batteries Based on First-Life Historical Degradation Data Using Predictive Time-Series Algorithms

Salek,

Resalati,

Azizi

et al. 2024

Mathematics

Self Cite

View full text Add to dashboard Cite

The exponential growth of electric and hybrid vehicles, now numbering close to 6 million on the roads, has highlighted the urgent need to address the environmental impact of their lithium-ion batteries as they approach their end-of-life stages. Repurposing these batteries as second-life batteries (SLBs) for less demanding non-automotive applications is a promising avenue for extending their usefulness and reducing environmental harm. However, the shorter lifespan of SLBs brings them perilously close to their ageing knee, a critical point where further use risks thermal runaway and safety hazards. To mitigate these risks, effective battery management systems must accurately predict the state of health of these batteries. In response to this challenge, this study employs time-series artificial intelligence (AI) models to forecast battery degradation parameters using historical data from their first life cycle. Through rigorous analysis of a lithium-ion NMC cylindrical cell, the study tracks the trends in capacity and internal resistance fade across both the initial and second life stages. Leveraging the insights gained from first-life data, predictive models such as the Holt–Winters method and the nonlinear autoregressive (NAR) neural network are trained to anticipate capacity and internal resistance values during the second life period. These models demonstrate high levels of accuracy, with a maximum error rate of only 2%. Notably, the NAR neural network-based algorithm stands out for its exceptional ability to predict local noise within internal resistance values. These findings hold significant implications for the development of specifically designed battery management systems tailored for second-life batteries.

show abstract

“…If the repair processes are not able to restore higher performance and the traction battery is still functional and safe, it may have other uses. The second life of a traction battery can usually be in the form of a stationary energy storage device [77,78]. In this application, the maximum energy capacity is not as important as in a vehicle, where it directly affects the range of the electric vehicle.…”

Section: Introductionmentioning

confidence: 99%

A Method for Assessing the Technical Condition of Traction Batteries Using the Metalog Family of Probability Distributions

Caban,

Małek,

Kroczyński

2024

Energies

View full text Add to dashboard Cite

The aim of the research presented in the article is to use the Metalog family of probability distributions to assess the technical condition of traction battery packs from electric and hybrid vehicles. The description of the research object, which is a battery pack from a hybrid vehicle, will be provided. Then, a system for controlled charging and discharging of individual cells in a battery pack will be reviewed. It is an essential diagnostic and research device used to determine the capacity of individual cells. The capacity values of all battery cells will then be analyzed using the Metalog probability distribution family. The use of this tool allows us to determine the Probability Density Function for the entire battery pack. Based on this, the diagnostician is able to assess the technical condition of the tested package and decide on its further fate. It can be intended for repair, employed as a stationary energy storage facility, or used for disposal. The algorithm for assessing the technical condition of traction batteries proposed by the authors can be used in all battery packs regardless of the type of cells used and their energy capacity.

show abstract

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

Cited by 6 publications

References 123 publications

Fuzzy Logic-Based Energy Management System for Regenerative Braking of Electric Vehicles with Hybrid Energy Storage System

Fuzzy Logic-Based Energy Management System for Regenerative Braking of Electric Vehicles with Hybrid Energy Storage System

State of Health Prediction of Electric Vehicles’ Retired Batteries Based on First-Life Historical Degradation Data Using Predictive Time-Series Algorithms

A Method for Assessing the Technical Condition of Traction Batteries Using the Metalog Family of Probability Distributions

Contact Info

Product

Resources

About