Abstract
Lithium-ion batteries exhibit significant performance degradation such as power/energy capacity loss and life cycle reduction in low-temperature conditions. Hence, the Li-ion battery pack is heated before usage to enhance its performance and lifetime. Recently, many internal heating methods have been proposed to provide fast and efficient pre-heating. However, the proposed methods only consider a combination of unit cells while the internal heating should be implemented for multiple groups within a battery pack. In this study, we investigated the possibility of timing control to simultaneously obtain balanced temperature and state of charge (SOC) between each cell by considering geometrical and thermal characteristics of the battery pack. The proposed method schedules the order and timing of the charge/discharge period for geometrical groups in a battery pack during internal pre-heating. We performed a pack-level simulation with realistic electro-thermal parameters of the unit battery cells by using the mutual pulse heating strategy for multi-layer geometry to acquire the highest heating efficiency. The simulation results for heating from −30 ∘ C to 10 ∘ C indicated that a balanced temperature-SOC status can be achieved via the proposed method. The temperature difference can be decreased to 0.38 ∘ C and 0.19% of the SOC difference in a heating range of 40 ∘ C with only a maximum SOC loss of 2.71% at the end of pre-heating.
Highlights
Lithium-ion batteries are widely used for various battery-powered applications due to numerous technical advantages
We examined the possibility of timing control to simultaneously obtain a balanced temperature and state of charge (SOC) by considering the geometrical characteristics of a battery pack
The voltage, current, and temperature responses during mutual pulse heating from Tamb = −30 ◦ C are shown in Figures 11 and 12
Summary
Lithium-ion batteries are widely used for various battery-powered applications due to numerous technical advantages. Modern Li-ion batteries exhibit an explosive feature at high temperatures. Many studies revealed that higher temperature leads to excessive ageing of the battery [2]. It is reported that a commercial 18650 lithium-ion battery can only provide 5% of nominal energy with 1.25% of power capacity at −40 ◦ C where the nominal capacity is determined at 20 ◦ C [3]. The service quality of the battery-powered applications significantly deteriorates in low-temperature conditions. The driving range of EVs significantly decreases in cold weather because the internal resistance of the batteries increases considerably at low temperature, and this results in heavy losses of energy and power capacity [4,5]
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