共晶体系
复合数
材料科学
阶段(地层学)
相变
热能储存
电池(电)
盐(化学)
相(物质)
化学工程
热的
复合材料
化学
热力学
有机化学
工程物理
微观结构
工程类
古生物学
功率(物理)
物理
生物
作者
Wensheng Yang,Zhubin Yao,Xinxi Li,Canbing Li,Ya Mao,Xiaoyu Zhou,Wei Jia,Yuhang Wu,Weifu Xu,Rui Liang,Xiaozhou Liu,Lifan Yuan,Zhizhou Tan
标识
DOI:10.1016/j.gee.2025.05.011
摘要
To address the challenge of balancing thermal management and thermal runaway mitigation, it is crucial to explore effective methods for enhancing the safety of lithium-ion battery systems. Herein, an innovative hydrated salt composite phase change material (HSCPCM) with dual phase transition temperature zones has been proposed. This HSCPCM, denoted as SDMA10, combines hydrophilic modified expanded graphite, an acrylic emulsion coating, and eutectic hydrated salts to achieve leakage prevention, enhanced thermal stability, cycling stability, and superior phase change behavior. Battery modules incorporating SDMA10 demonstrate significant thermal control capabilities. Specifically, the cylindrical battery modules with SDMA10 can maintain maximum operating temperatures below 55 °C at 4 C discharge rate, while prismatic battery modules can keep maximum operating temperatures below 65 °C at 2 C discharge rate. In extreme battery overheating conditions simulated using heating plates, SDMA10 effectively suppresses thermal propagation. Even when the central heating plate reaches 300 °C, the maximum temperature at the module edge heating plates remains below 85 °C. Further, compared to organic composite phase change materials (CPCMs), the battery module with SDMA10 can further reduce the peak thermal runaway temperature by 93 °C and delay the thermal runaway trigger time by 689 s, thereby significantly decreasing heat diffusion. Therefore, the designed HSCPCM integrates excellent latent heat storage and thermochemical storage capabilities, providing high thermal energy storage density within the thermal management and thermal runaway threshold temperature range. This research will offer a promising pathway for improving the thermal safety performance of battery packs in electric vehicle and other energy storage systems. This research presents an innovative hydrated salt composite phase change material encapsulated with modifying expanded graphite (MEG) and acrylic emulsion (AE). The adhesion interactions are significantly improved owing to synergic effect between MEG and AE. It plays an important role in controlling temperature distribution and suppressing thermal runaway for battery module. • Modified expanded graphite (MEG) and acrylic emulsion (AE) are encapsulated hydrated salt. • Hydrated salt phase change material (SDMA10) are doubly encapsulated with MEG and AE. • SDMA10 exhibit high impermeability, water retention and flammable retardant properties. • SDMA10 display high thermal storage between 40-60°C and 100-150°C temperature ranges. • SDMA10 has delayed thermal runaway triggering time and suppresses heat propagation.
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