锂离子电池异构建模及内部传质机理探究:粒径分布的影响

Heterogeneous modeling and internal mass transfer mechanism of lithium-ion batteries:effect of particle size distribution

锂离子电池是目前应用较广的储能设备,具有能量密度高、使用寿命长等特点。随着锂离子电池正极材料实际能量密度接近理论值,电池组装工艺参数的优化成了提升其性能的重要途径,其中电极颗粒粒径及分布是十分重要的参数。因此,本文针对石墨-LiFePO4体系锂离子电池,利用异构模型构建单粒径和双粒径电极的几何结构,再结合Newman模型模拟其放电过程,定量研究了正极材料粒径分布对锂离子电池性能的影响,探究了存在粒径分布的电极中不同粒径的颗粒在充放电过程的作用机制。模拟结果表明,粒径的减小可以减小固相扩散系数对电池性能的影响,但会增加液相扩散阻力;而粒径的分布可以促进锂离子在电解液中的扩散,提高小粒径颗粒的锂嵌入量,但会引起极化增大,导致大颗粒的锂嵌入量降低。粒径分布宽度越大,总体粒度越大,锂离子电池的能量密度越小。选择合适的粒径分布宽度,适当减小总体粒度的大小,能有效提升电极的能量密度。研究结果对于锂离子电池电极活性材料颗粒粒径分布的选择提供了有益的基础知识和指导。

Lithium-ion batteries,as a kind of energy storage device with high energy density and long service life,have been widely applied in many fields.As the actual energy densities of cathode materials approach their theoretical values,the optimization of assembling parameters has become a crucial way to improve the performance of lithium-ion batteries.And the particle size distribution of the electrode particles is a very important parameter.In this work,heterogeneous models were used to construct geometry of electrode with single-sized particles and bimodal-sized LiFePO4(LFP)particles.Then the corresponding discharge processes of C-LFP system were quantitatively simulated by Newman model to investigate the impact of particle size distribution on the performance of lithium-ion batteries.The simulation results show that the reduction of the particle size reduced the influence of solid phase diffusion coefficient on battery performance,but increased the liquid phase diffusion resistance.Proper particle size distribution of active material could promote the diffusion of lithium ion in electrolyte and increase the lithium insertion amount inside the small particles,but cause heavier polarization,thus decreasing the lithium insertion amount inside the large particles.The wider distribution of the particles and the larger overall particle size,the smaller the energy density of the lithium ion battery.Choosing an appropriate active particle size with proper distribution can effectively enhance the energy density of lithium-ion batteries.The research results provide useful basic knowledge and guidance for the selection of particle size distribution of electrode active materials for lithiumion batteries.