Extreme fast charging of batteries using thermal switching and self-heating

TL;DR

This paper introduces a thermal switching-based charging protocol that enables electric vehicle batteries to charge in under 15 minutes for over 500 cycles, addressing key challenges in fast charging technology.

Contribution

The study proposes a novel thermally modulated charging protocol using active thermal switching, achieving ultra-fast charging without lithium plating in commercial lithium-ion batteries.

Findings

Charge time <15 min for high-energy LIBs

Over 500 charge cycles maintained

Achieved targets for energy density and capacity loss

Abstract

The long charge time of electric vehicles compared with the refueling time of gasoline vehicles, has been a major barrier to the mass adoption of EVs. Currently, the charge time to 80% state of charge in electric vehicles such as Tesla with fast charging capabilities is >30 minutes. For a comparable recharging experience as gasoline vehicles, governments and automobile companies have set <15 min with 500 cycles as the goal for extreme fast charging (XFC) of electric vehicles. One of the biggest challenges to enable XFC for lithium-ion batteries (LIBs) is to avoid lithium plating. Although significant research is taking place to enable XFC, no promising technology/strategy has still emerged for mainstream commercial LIBs. Here, we propose a thermally modulated charging protocol (TMCP) by active thermal switching for XFC, i.e., retaining the battery heat during XFC with the switch OFF for boosting the kinetics to avoid lithium plating while dissipating the heat after XFC with the switch ON for reducing side reactions. Our proposed TMCP strategy enables XFC of commercial high-energy-density LIBs with charge time <15 min and >500 cycles while simultaneously beating other targets set by US Department of energy (discharge energy density > 180 Wh/kg and capacity loss < 4.5%). Further, we develop a thermal switch based on shape memory alloy and demonstrate the feasibility of integrating our TMCP in commercial battery thermal management system.