[1]李继方,冯硕,石晓阳,等.基于分布式发电的储能系统能量管理策略[J].太阳能学报,2023,44(8):30-38. [2]HAKIMI S M,HASANKHANI A,SHAFIE-KHAH M, et al. Optimal sizing of renewable energy systems in a microgrid considering electricity market interaction and reliability analysis[J]. Electric Power Systems Research, 2022, 203:107678. [3]单恩泽,王鹿军.基于双阈值的高精度锂电池主被动均衡策略[J].电气传动,2021,51(11):40-47. [4]贲礼进. 光伏发电锂电池储能均衡方法的研究[J]. 电源技术,2015,39(11):2438-2440,2486. [5]沈馨,张睿,赵辰孜,等.金属锂电池中力-电化学机制研究进展[J].储能科学与技术,2022,11(9):2781-2797. [6]LAMAN F C,BRANDT K. Effect of discharge current on cycle life of a rechargeable lithium battery[J]. Journal of Power Sources, 1988, 24(3):195-206. [7]KORNILOV D,PENKI T R,CHEGLAKOV A,et,al. Li/graphene oxide primary battery system and mechanism[J]. Battery Energy,2022,1(2): 20210002. [8]刘日鑫,张振杰,李浩宇,等.高比能锂离子电池富锂正极材料研究进展[J].硅酸盐学报,2022,50(1):70-83. [9]张华栋,杨明,李建祥,等.一种基于单元数量控制的电动汽车充换电站电池充放电策略[J].电工电能新技术,2016,35(8):57-65. [10]ADANY R, AURBACH D,KRAUS S. Switching algorithms for extending battery life in electric vehicles[J]. Journal of Power Sources, 2013, 231:50-59. [11]张志超,郑莉莉,杜光超,等.锂离子电池充放电过程中产热特性研究综述[J].储能科学与技术,2019,8(增刊1):31-37. [12]YU Y, GUO Z P, MO Y F,et,al. Post-lithium battery materials and technology[J]. EcoMat,2020,2(4):e12003. [13]LI J W,JI Y C,SONG H R,et al. Insights into the interfacial degradation of high-voltage all-solid-state lithium batteries[J].Nano-Micro Letters,2022,14:191. [14]ZHANG S Z,ZHANG X W.A comparative study of different online model parameters identification methods for lithium-ion battery[J].2021(10):2312-2327. [15]李晨,刘桂林,王春宁,等.热失控下锂电池内部反应综述[J].电源技术,2020,44(12):1851-1854. [16]CHE Y H,DENG Z W,TANG X L,et al. Lifetime and aging degradation prognostics for lithium-ion battery packs based on a cell to pack method[J].Chinese Journal of Mechanical Engineering, 2022, 35(01):203-218. [17]祝庆伟,俞小莉,吴启超,等.高能量密度锂离子电池老化半经验模型[J].储能科学与技术,2022,11(7):2324-2331. [18]汪秋婷,戚伟.基于锂电池退化模型的混合动力最优控制[J].控制工程,2021,28(9):1725-1730. |