2022年中国储能技术研究进展

doi:10.19799/j.cnki.2095-4239.2023.0330

储能科学与技术 ›› 2023, Vol. 12 ›› Issue (5): 1516-1552.doi: 10.19799/j.cnki.2095-4239.2023.0330

2022年中国储能技术研究进展

陈海生¹(), 李泓², 徐玉杰¹, 陈满³, 王亮¹, 戴兴建¹, 徐德厚⁴, 唐西胜⁵, 李先锋⁶, 胡勇胜², 马衍伟⁵, 刘语¹, 苏伟⁷, 王青松⁸, 陈军⁹, 卓萍¹⁰, 肖立业⁵, 周学志¹, 冯自平¹¹, 蒋凯¹², 尉海军¹³, 唐永炳¹⁴, 陈人杰¹⁵, 刘亚涛¹⁶, 张宇鑫¹, 林曦鹏¹, 郭欢¹, 张涵¹, 张长昆⁶, 胡东旭¹, 容晓晖², 张熊⁵, 金凯强⁸, 姜丽华⁸, 彭煜民³, 刘世奇¹³, 朱轶林¹, 王星¹, 周鑫¹, 欧学武¹⁴, 庞全全¹⁶, 俞振华¹⁷, 刘为¹⁷, 岳芬¹⁷, 李臻¹⁷, 宋振¹⁷, 王志峰⁵, 宋文吉¹¹, 林海波¹⁸, 李杰才¹⁸, 易斌⁷, 李福军⁹, 潘新慧¹⁹, 李丽¹⁵, 马一鸣³, 李煌⁸

^1.中国科学院工程热物理研究所
^2.中国科学院物理研究所，北京 100190
^3.南方电网储能股份有限公司，广州广东 510623
^4.毕节高新技术产业开发区国家能源大规模物理储能技术研发中心，贵州毕节 551712
^5.中国科学院电工研究所，北京 100190
^6.中国科学院大连化学物理研究所，辽宁大连 116000
^7.南方电网电力科技股份有限公司，广东广州 510080
^8.中国科学技术大学火灾科学国家重点实验室，安徽合肥 230026
^9.南开大学，天津 300071
^10.应急管理部天津消防研究所，天津 300381
^11.中国科学院广州能源研究所，广东广州 510640
^12.华中科技大学电气与电子工程学院，湖北武汉 430074
^13.北京工业大学材料与制造学部先进电池材料与器件研究所，北京 100124
^14.中国科学院深圳先进技术研究院，广东深圳 518055
^15.北京理工大学，北京 100081
^16.北京大学材料科学与工程学院，北京 100871
^17.中关村储能产业技术联盟，北京 100190
^18.吉林大学，吉林长春 130012
^19.北京理工大学前沿技术研究院，山东济南 250307

收稿日期:2023-05-09 修回日期:2023-05-15 出版日期:2023-05-05 发布日期:2023-05-29
通讯作者: 陈海生,李泓,徐玉杰,陈满,王亮,戴兴建,徐德厚,唐西胜,李先锋,胡勇胜,马衍伟,刘语,苏伟,王青松,陈军,卓萍,肖立业,周学志,冯自平,蒋凯,尉海军,唐永炳,陈人杰,刘亚涛 E-mail:chen_hs@iet.cn
作者简介:陈海生（1977—），男，研究员，博士，研究方向为新型大规模储能技术、传热与储热（冷）特性等，E-mail：chen_hs@iet.cn
第一联系人：共同第一作者：李泓，徐玉杰，陈满，王亮，戴兴建，徐德厚，唐西胜，李先锋，胡勇胜，马衍伟，刘语，苏伟，王青松，陈军，卓萍，肖立业，周学志，冯自平，蒋凯，尉海军，唐永炳，陈人杰，刘亚涛。
基金资助:
国家杰出青年科学基金(51925604);内蒙古自治区科技重大专项(2020ZD0017);中国科学院国际合作局国际伙伴计划(182211KYSB20170029);中国科学院战略性先导科技专项（A类）(XDA21070200)

Research progress on energy storage technologies of China in 2022

Haisheng CHEN¹(), Hong LI², Yujie XU¹, Man CHEN³, Liang WANG¹, Xingjian DAI¹, Dehou XU⁴, Xisheng TANG⁵, Xianfeng LI⁶, Yongsheng HU², Yanwei MA⁵, Yu LIU¹, Wei SU⁷, Qingsong WANG⁸, Jun CHEN⁹, Ping ZHUO¹⁰, Liye XIAO⁵, Xuezhi ZHOU¹, Ziping FENG¹¹, Kai JIANG¹², Haijun YU¹³, Yongbing TANG¹⁴, Renjie CHEN¹⁵, Yatao LIU¹⁶, Yuxin ZHANG¹, Xipeng LIN¹, Huan GUO¹, Han ZHANG¹, Changkun ZHANG⁶, Dongxu HU¹, Xiaohui RONG², Xiong ZHANG⁵, Kaiqiang JIN⁸, Lihua JIANG⁸, Yumin PENG³, Shiqi LIU¹³, Yilin ZHU¹, Xing WANG¹, Xin ZHOU¹, Xuewu OU¹⁴, Quanquan PANG¹⁶, Zhenhua YU¹⁷, Wei LIU¹⁷, Fen YUE¹⁷, Zhen LI¹⁷, Zhen SONG¹⁷, Zhifeng WANG⁵, Wenji SONG¹¹, Haibo LIN¹⁸, Jiecai LI¹⁸, Bin YI⁷, Fujun LI⁹, Xinhui PAN¹⁹, Li LI¹⁵, Yiming MA³, Huang LI⁸

^1.Institute of Engineering Thermophysics, Chinese Academy of Sciences, 2Institute of Physics, Chinese Academy of Sciences, Beijing 100190, China
^3.Southern Power Grid Energy Storage Co. , Ltd. , Guangzhou 510623, Guangdong, China
^4.National Energy Large Scale Physical Energy Storage Technologies R&D Center of Bijie High-tech Industrial Development Zone, Bijie 551712, Guizhou, China
^5.Institute of Electrical Engineering, Chinese Academy of Sciences, Beijing 100190, China
^6.Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian 116023, Liaoning, China
^7.Southern Power Grid Power Technology Co. , Ltd. , Guangzhou 510080, Guangdong, China
^8.State Key Laboratory of Fire Science, University of Science and Technology of China, Hefei 230026, Anhui, China
^9.Nankai University, Tianjin 300071, China
^10.Tianjin Fire Science and Technology Research Institute of MEM, Tianjin 300381, China
^11.Guangzhou Institute of Energy Conversion, Chinese Academy of Sciences, Guangzhou 510640, Guangdong, China
^12.School of Electrical and Electronic Engineering, Huazhong University of Science and Technology, Wuhan 430074, Hubei, China
^13.Institute of Advanced Battery Materials and Devices, Faculty of Materials and Manufacturing, Beijing University of;Technology, Beijing 100124, China
^14.Shenzhen Institute of Advanced Technology, inese Academy of Sciences, Shenzhen 518055, Guangdong, China
^15.Beijing Institute of Technology, Beijing 100081, China
^16.School of Materials Science and Engineering, Peking University, Beijing 100871, China
^17.China Energy Storage Alliance, Beijing 100190, China
^18.Jilin University, Changchun 130012, Jilin, China
^19.Advanced Technology Research Institute, Beijing Institute of Technology, Ji'nan 250307, Shandong, China

Received:2023-05-09 Revised:2023-05-15 Online:2023-05-05 Published:2023-05-29
Contact: Haisheng CHEN, Hong LI, Yujie XU, Man CHEN, Liang WANG, Xingjian DAI, Dehou XU, Xisheng TANG, Xianfeng LI, Yongsheng HU, Yanwei MA, Yu LIU, Wei SU, Qingsong WANG, Jun CHEN, Ping ZHUO, Liye XIAO, Xuezhi ZHOU, Ziping FENG, Kai JIANG, Haijun YU, Yongbing TANG, Renjie CHEN, Yatao LIU E-mail:chen_hs@iet.cn

摘要/Abstract

摘要：

本文对2022年度中国储能技术的研究进展进行了综述。通过对基础研究、关键技术和集成示范三方面的回顾和分析，总结了2022年中国储能领域的主要技术进展，包括抽水蓄能、压缩空气储能、飞轮储能、锂离子电池、铅蓄电池、液流电池、钠离子电池、超级电容器、新型储能技术、集成技术和消防安全技术等。结果表明，2022年中国储能技术在基础研究、关键技术和集成示范方面均有重要进展，中国已成为世界储能技术基础研究、技术研发和集成应用最活跃的国家。

关键词: 储能, 技术, 进展

Abstract:

Research progress on energy storage technologies of China in 2022 is reviewed in this paper. By reviewing and analyzing three aspects in terms of fundamental study, technical research, integration and demonstration, the progress on China's energy storage technologies in 2022 is summarized including hydro pumped energy storage, compressed air energy storage, flywheel, lithium-ion battery, lead battery, flow battery, sodium-ion battery, supercapacitor, new technologies, integration technology, firecontrol technology etc. It is found that important achievements in energy storage technologies have been obtained during 2022, and China is now the most active country in the world in energy storage fields on all the three aspects of fundamental study, technical research, integration and application.

Key words: energy storage, technology, progress

中图分类号:

TK 02

陈海生, 李泓, 徐玉杰, 陈满, 王亮, 戴兴建, 徐德厚, 唐西胜, 李先锋, 胡勇胜, 马衍伟, 刘语, 苏伟, 王青松, 陈军, 卓萍, 肖立业, 周学志, 冯自平, 蒋凯, 尉海军, 唐永炳, 陈人杰, 刘亚涛, 张宇鑫, 林曦鹏, 郭欢, 张涵, 张长昆, 胡东旭, 容晓晖, 张熊, 金凯强, 姜丽华, 彭煜民, 刘世奇, 朱轶林, 王星, 周鑫, 欧学武, 庞全全, 俞振华, 刘为, 岳芬, 李臻, 宋振, 王志峰, 宋文吉, 林海波, 李杰才, 易斌, 李福军, 潘新慧, 李丽, 马一鸣, 李煌. 2022年中国储能技术研究进展[J]. 储能科学与技术, 2023, 12(5): 1516-1552.

Haisheng CHEN, Hong LI, Yujie XU, Man CHEN, Liang WANG, Xingjian DAI, Dehou XU, Xisheng TANG, Xianfeng LI, Yongsheng HU, Yanwei MA, Yu LIU, Wei SU, Qingsong WANG, Jun CHEN, Ping ZHUO, Liye XIAO, Xuezhi ZHOU, Ziping FENG, Kai JIANG, Haijun YU, Yongbing TANG, Renjie CHEN, Yatao LIU, Yuxin ZHANG, Xipeng LIN, Huan GUO, Han ZHANG, Changkun ZHANG, Dongxu HU, Xiaohui RONG, Xiong ZHANG, Kaiqiang JIN, Lihua JIANG, Yumin PENG, Shiqi LIU, Yilin ZHU, Xing WANG, Xin ZHOU, Xuewu OU, Quanquan PANG, Zhenhua YU, Wei LIU, Fen YUE, Zhen LI, Zhen SONG, Zhifeng WANG, Wenji SONG, Haibo LIN, Jiecai LI, Bin YI, Fujun LI, Xinhui PAN, Li LI, Yiming MA, Huang LI. Research progress on energy storage technologies of China in 2022[J]. Energy Storage Science and Technology, 2023, 12(5): 1516-1552.

图/表 11

图1

图2

图3

表1

2022年中国储能关键技术与示范进展"

技术类型	关键技术进展	集成示范进展
抽水蓄能	①大型全功率变速恒频抽水蓄能机组变速抽水机组；②13叶片、9叶片等新型转轮水泵水轮机；③大容量蓄能机组导水机构数字化虚拟预装技术；④多厂站集中监控技术等	①百万千瓦级抽水蓄能电站成套设备实现国产化；②我国首台全功率变速恒频抽蓄机组成功投运；③我国首个单机40万千瓦全功率变速恒频抽蓄机组启动
压缩空气储能	①突破300 MW多级膨胀机、高效蓄热换热器等关键技术；②首台100 MW系统压缩机和膨胀机完成第三方测试；效率分别为87.5%和91.8%；③首台100 MW系统蓄热器完成第三方测试，蓄热效率超过98%	①山东肥城10 MW先进CAES示范项目商业运行1周年；②江苏金坛60 MW压缩空气储能并网发电；③河北张家口国际首套100 MW先进压缩空气储能示范项目顺利并网发电；④山东肥城二期300 MW、江苏淮安465 MW工程项目启动
储热储冷	①多种基于多孔材料和石墨为骨架的复合相变和定形相变储热材料完成制备；②多通道结构相变储热单元技术；③储热系统耦合燃煤发电系统技术；④新一代直接蒸发冰浆技术	①相变储热等蓄热技术应用于冬奥会场馆；②甘肃敦煌国内最大的电极锅炉储热供暖项目；③江苏靖江首个熔盐储热75 MWh火电调峰调频项目；④青海贵南高海拔地区单体容量最大的固体蓄热式电锅炉投运；⑤中铁冷链标准化联运无源冷藏集装箱提供移动储冷解决方案
飞轮储能	①300 kW磁悬浮永磁同步电机技术；②飞轮储能结合其他储能实现短时高功率、长时大能量的复合储能技术；③飞轮阵列协调控制技术	①2 MW飞轮储能在铁路牵引回收制动能量示范；②MW级飞轮阵列在青海风光储项目实现示范；③两台1 MW飞轮储能在青岛地铁3号线顺利并网
铅蓄电池	①高电化学活性和铅炭兼容的新型炭材料；②提高电池容量等性能的优质电解液添加剂	①10 MW/97.312 MW用户侧储能项目工程投运；②100.8 MW/1061.683 MWh铅碳储能电站完成招标
锂离子电池	①预锂化技术、液冷技术、超大电池技术等；②高能量密度半固态电池技术；③硫基电池、锰基电池技术等	①宁德时代推出长寿命液冷储能集装箱EnerC；②宁夏液冷型100 MW/200 MWh储能电站成功并网；③混合固液锂电池首次实现MWh级的应用示范等
液流电池	①高功率60 kW全钒液流电堆技术；②非氟阳离子传导膜技术；③30 kW级锌溴液流电池电堆集成技术	①全球首套100 MW/400 MWh全液流电池储能调峰电站正式并网发电；②1 MW级铁铬液流电池储能系统进入调试阶段；③多个100 MW级产线项目开工建设
钠离子电池	①正负极材料制备及放大技术；②电解液/隔膜体系优选技术；③高安全、高倍率和宽温电芯设计制造技术④电池的安全性设计与评价技术等	①全球首款12.6 kWh钠离子电池家用储能系统发布；②30 MW/60 MWh钠离子电池储能系统完成招标；③率先实现了钠离子电池材料和GWh电芯量产
超级电容器	①活性炭制备技术、隔膜制备技术、器件制备技术、模组快充技术；②高电压宽温区微型电容器高效运行技术；③能量型锂离子超级电容技术；④高电压耐热性超级电容技术	①1 MW/0.1 MWh超级电容混合储能系统示范运行；②超级电容和燃料电池复合组成的全球首列时速160公里列车研制成功；③世界首艘纯超级电容动力渡轮“新生态”号运行
储能新技术	①重力储能技术；②热泵储电技术；③压缩二氧化碳；④液态金属技术；⑤双离子电池技术；⑥有机储能电池技术等	—
集成技术	①电池功率变换拓扑技术；②电池系统智能诊断技术和内功率分配技术；③高效智能温控技术和液冷技术；④规模化集群控制技术	①高效智能风冷和浸没式液冷两种高能量密度1500 V磷酸铁锂储能系统示范；②采用构网型储能变流器的储能示范项目应用
消防安全技术	①纳米强化、微热管、混合式等热管理新技术；②热失控火灾预警技术；③热失控抑制及灭火技术，相变隔热、全氟己酮、液氮灭火技术等	①多参数融合预警技术和全氟己酮补偿式喷射技术示范；②管网式七氟丙烷灭火系统结合供水管网的自动喷水灭火系统

表1

图4

图5

图6

图7

图8

图9

图10

参考文献 284

1	陈海生, 刘畅, 徐玉杰, 等. 储能在碳达峰碳中和目标下的战略地位和作用[J]. 储能科学与技术, 2021, 10(5): 1477-1485.
	CHEN H S, LIU C, XU Y J, et al. The strategic position and role of energy storage under the goal of carbon peak and carbon neutrality[J]. Energy Storage Science and Technology, 2021, 10(5): 1477-1485.
2	国家发改委国家能源局关于印发《"十四五"新型储能发展实施方案》的通知[EB/OL]. (2022-01-29) https://www.ndrc.gov.cn/xxgk/zcfb/tz/202203/t20220321_1319772_ext.html.
3	李先锋, 张洪章, 郑琼, 等. 能源革命中的电化学储能技术[J]. 中国科学院院刊, 2019, 34(4): 443-449.
	LI X F, ZHANG H Z, ZHENG Q, et al. Electrochemical energy storage technology in energy revolution[J]. Bulletin of Chinese Academy of Sciences, 2019, 34(4): 443-449.
4	陈海生, 凌浩恕, 徐玉杰. 能源革命中的物理储能技术[J]. 中国科学院院刊, 2019, 34(4): 450-459.
	CHEN H S, LING H S, XU Y J. Physical energy storage technology in energy revolution[J]. Bulletin of Chinese Academy of Sciences, 2019, 34(4): 450-459.
5	陈海生. "双碳"目标下的储能发展[J]. 中国电力企业管理, 2021(22): 23-24.
	CHEN H S. Energy storage development under the goal of "double carbon"[J]. China Power Enterprise Management, 2021(22): 23-24.
6	陈海生, 李泓, 马文涛, 等. 2021年中国储能技术研究进展[J]. 储能科学与技术, 2022, 11(3): 1052-1076.
	CHEN H S, LI H, MA W T, et al. Research progress of energy storage technology in China in 2021[J]. Energy Storage Science and Technology, 2022, 11(3): 1052-1076.
7	中国政府网. 国家发展改革委、国家能源局部署加快"十四五"时期抽水蓄能项目开发建设[EB/OL]. [2022-04-07]. http://www.gov.cn/xinwen/2022-04/07/content_5683819.htm.
8	CHEN P, DENG Y M, ZHANG X G, et al. Degradation trend prediction of pumped storage unit based on MIC-LGBM and VMD-GRU combined model[J]. Energies, 2022, 15(2): 605.
9	REN Y, ZHANG L L, CHEN J T, et al. Noise reduction study of pressure pulsation in pumped storage units based on sparrow optimization VMD combined with SVD[J]. Energies, 2022, 15(6): 2073.
10	唐拥军, 倪晋兵, 肖业祥. 基于噪声分析的抽水蓄能机组运行预警技术研究[J]. 水电与抽水蓄能, 2022, 8(3): 35-38, 52.
	TANG Y J, NI J B, XIAO Y X. Study on operation warning technique for pump storage unit based on analysis of noise[J]. Hydropower and Pumped Storage, 2022, 8(3): 35-38, 52.
11	朱莎莎, 杨光, 林雯雯. 抽水蓄能电站甩负荷实测数据处理与分析[J]. 水利规划与设计, 2022(5): 78-85, 121.
	ZHU S S, YANG G, LIN W W. Processing and analysis of measured load rejection data of pumped storage power station[J]. Water Resources Planning and Design, 2022(5): 78-85, 121.
12	LUO Y, SHAO D J, ZHAO J J, et al. Stability analysis of Tianchi pumped storage power station connected to central China power grid[C]//2022 7th Asia conference on power and electrical engineering (ACPEE). April 15-17, 2022, Hangzhou, China. IEEE, 2022: 606-612.
13	冯陈, 周大庆, 郑源, 等. 基于精细化建模的抽水蓄能机组低水头背靠背启动多目标优化[J]. 中国电机工程学报, 2023, 43(8): 3059-3071.
	FENG C, ZHOU D Q, ZHENG Y, et al. Multi-objective optimization of back-to-back starting process for pumped storage units at low head area based on refined model[J]. Proceedings of the CSEE, 2023, 43(8): 3059-3071.
14	吴伟亮, 刘细平, 黄朝志, 等. 大型抽水蓄能机组静止变频起动控制技术研究[J]. 水电能源科学, 2022, 40(6): 196-200, 206.
	WU W L, LIU X P, HUANG C Z, et al. Research on static frequency start-up control technology for large pumped storage unit[J]. Water Resources and Power, 2022, 40(6): 196-200, 206.
15	陈伟伟, 张增强, 张高航, 等. 计及需求响应及抽水蓄能的含风电系统鲁棒机组组合[J]. 电力工程技术, 2022, 41(2): 75-82.
	CHEN W W, ZHANG Z Q, ZHANG G H, et al. Robust unit commitment of power systems integrated wind power considering demand response and pumped storage units[J]. Electric Power Engineering Technology, 2022, 41(2): 75-82.
16	JI L Y, LI C B, LI X P, et al. Multi-method combination site selection of pumped storage power station considering power structure optimization[J]. Sustainable Energy Technologies and Assessments, 2022, 49: doi: 10.1016/j.seta.2021.101680.
17	MA S Y, ZHOU B Y, WANG Q W, et al. Study on technologies and applications of joint participation of pumped storage and electrochemical energy storage in power grid frequency modulation[C]//2022 5th Asia Conference on Energy and Electrical Engineering (ACEEE). July 8-10, 2022, Kuala Lumpur, Malaysia. IEEE, 2022: 73-78.
18	MISHRA A K, SINGH B, KIM T. An efficient and credible grid-interfaced solar PV water pumping system with energy storage[J]. IEEE Journal of Photovoltaics, 2022, 12(3): 880-887.
19	罗远翔, 李鑫明, 潘超, 等. 含风电的双馈抽水蓄能机组协调调频策略[J]. 电力系统保护与控制, 2022, 50(17): 76-85.
	LUO Y X, LI X M, PAN C, et al. Coordinated frequency modulation strategy of doubly fed pumped storage units with wind power[J]. Power System Protection and Control, 2022, 50(17): 76-85.
20	姬嘉明. 考虑抽水蓄能电站的风光互补发电系统的优化调度研究[D]. 郑州: 华北水利水电大学, 2022.
	JI J M. Study on optimal dispatching of wind-solar hybrid power generation system considering pumped storage power station[D]. Zhengzhou: North China University of Water Resources and Electric Power, 2022.
21	LI C P, LI J, LI J H, et al. Optimization strategy of secondary frequency modulation based on dynamic loss model of the energy storage unit[J]. Journal of Energy Storage, 2022, 51: doi: 10.1016/j.est.2022.104425.
22	LI Y, LI O T, WU F, et al. Coordinated multi-objective capacity optimization of wind-photovoltaic-pumped storage hybrid system[J]. Energy Reports, 2022, 8: 1303-1310.
23	桑林卫, 卫璇, 许银亮, 等. 抽水蓄能助力风光稳定外送的最佳配置策略[J]. 中国电力, 2022, 55(12): 86-90, 123.
	SANG L W, WEI X, XU Y L, et al. The optimal allocation strategy of pumped storage for the collaborative operation with wind/solar generation[J]. Electric Power, 2022, 55(12): 86-90, 123.
24	CHANG Y H, LIU S Z, WANG L, et al. Research on low-carbon economic operation strategy of renewable energy-pumped storage combined system[J]. Mathematical Problems in Engineering, 2022, 2022: 1-13.
25	LUO Y X, WANG Y H, LIU C, et al. Two-stage robust optimal scheduling of wind power-photovoltaic-thermal power-pumped storage combined system[J]. IET Renewable Power Generation, 2022, 16(13): 2881-2891.
26	贾鑫, 蔡卫江, 于爽, 等. 可变速抽水蓄能机组协调控制单元设计与功能研究[C]//中国水力发电工程学会自动化专委会2022年年会暨全国水电厂智能化应用学术交流会会议论文集. 南京: 中国水力发电工程学会自动化专业委员会, 2022: 176-180.
27	DENG Y W, WANG P F, MORABITO A, et al. Dynamic analysis of variable-speed pumped storage plants for mitigating effects of excess wind power generation[J]. International Journal of Electrical Power & Energy Systems, 2022, 135: doi: 10.1016/j.ijepes. 2021.107453.
28	赵志高, 杨建东, 董旭柱, 等. 基于动态实验的双馈抽水蓄能机组空载特性与变速演化[J]. 中国电机工程学报, 2022, 42(20): 7439-7451.
	ZHAO Z G, YANG J D, DONG X Z, et al. No-load characteristics and variable speed evolution of doubly-fed pumped storage unit based on dynamic experiment platform[J]. Proceedings of the CSEE, 2022, 42(20): 7439-7451.
29	王博, 张金仙, 胡金明, 等. 可变速抽水蓄能电机振动和噪声优化分析[J]. 水电站机电技术, 2022, 45(2): 48-53.
	WANG B, ZHANG J X, HU J M, et al. Optimization analysis of vibration and noise of variable speed pumped storage motor[J]. Mechanical & Electrical Technique of Hydropower Station, 2022, 45(2): 48-53.
30	乔照威, 孙玉田, 戈宝军. 可变速抽水蓄能发电电动机功率特性分析[J]. 大电机技术, 2022(3): 8-13.
	QIAO Z W, SUN Y T, GE B J. Power performance analysis of variable speed pumped storage generator motor[J]. Large Electric Machine and Hydraulic Turbine, 2022(3): 8-13.
31	CHEN Y H, XU W, LIU Y, et al. Modeling and transient response analysis of doubly-fed variable speed pumped storage unit in pumping mode[J]. IEEE Transactions on Industrial Electronics, 2023, 70(10): 9935-9947.
32	陈亚红, 邓长虹, 刘玉杰, 等. 抽水工况双馈可变速抽蓄机组机电暂态建模及有功-频率耦合特性[J]. 中国电机工程学报, 2022, 42(3): 942-957.
	CHEN Y H, DENG C H, LIU Y J, et al. Electromechanical transient modelling and active power-frequency coupling characteristics of doubly-fed variable speed pumped storage under pumping mode[J]. Proceedings of the CSEE, 2022, 42(3): 942-957.
33	CHEN Y H, XU W, LIU Y, et al. Small-signal system frequency stability analysis of the power grid integrated with type-II doubly-fed variable speed pumped storage[J]. IEEE Transactions on Energy Conversion, 2023, 38(1): 611-623.
34	SHI L J, LAO W J, WU F, et al. Frequency regulation control and parameter optimization of doubly-fed induction machine pumped storage hydro unit[J]. IEEE Access, 2022, 10: 102586-102598.
35	滕军, 吴新平, 吴林波, 等. 海水抽水蓄能电站设计关键技术问题研讨[J]. 中国农村水利水电, 2022(1): 159-162.
	TENG J, WU X P, WU L B, et al. Research on the key technical problems in designing seawater pumped storage power stations[J]. China Rural Water and Hydropower, 2022(1): 159-162.
36	卢开放, 侯正猛, 孙伟, 等. 云南省矿井抽水蓄能电站潜力评估与建设关键技术[J]. 工程科学与技术, 2022, 54(1): 136-144.
	LU K F, HOU Z M, SUN W, et al. Potential evaluation and construction key technologies of pumped-storage power stations in mines of Yunnan Province[J]. Advanced Engineering Sciences, 2022, 54(1): 136-144.
37	北极星电力网. 国内首台全功率变速恒频抽蓄机组研制成功[EB/OL]. [2022-05-16]. https://news.bjx.com.cn/html/20220516/1225181.shtml.
38	世纪新能源网. 2022年这8个抽蓄电站相继全面投产[EB/OL]. [2022-12-29]. https://www.ne21.com/news/show-174951.html.
39	新浪财经. 2022年"水火核"重大新闻[EB/OL]. [2023-01-02]. https://finance.sina.com.cn/jjxw/2023-01-02/doc-imxyuyam6083081.shtml.
40	LV H N, CHEN Y P, WU J F, et al. Performance of isobaric adiabatic compressed humid air energy storage system with shared equipment and road-return scheme[J]. Applied Thermal Engineering, 2022, 211: doi: 10.1016/j.applthermaleng.2022.118440.
41	CAO Z, ZHOU S H, HE Y, et al. Numerical study on adiabatic compressed air energy storage system with only one ejector alongside final stage compression[J]. Applied Thermal Engineering, 2022, 216: doi: 10.1016/j.applthermaleng.2022.119071.
42	RAN P, ZHANG H Y, QIAO Y, et al. Thermodynamic analysis for a novel steam injection adiabatic compressed air energy storage hybrid system[J]. Journal of Energy Storage, 2022, 55: doi: 10.1016/j.est.2022.105424.
43	HUANG J J, XU Y J, GUO H, et al. Dynamic performance and control scheme of variable-speed compressed air energy storage[J]. Applied Energy, 2022, 325: doi: 10.1016/j.apenergy.2022.119338.
44	GUO H, XU Y J, HUANG L J, et al. Concise analytical solution and optimization of compressed air energy storage systems with thermal storage[J]. Energy, 2022, 258: doi: 10.1016/j.energy. 2022.124773.
45	HUANG L J, GUO H, XU Y J, et al. Influence of design point on off-design and cycling performance of compressed air energy storage systems-from key processes to the whole system[J]. Journal of Energy Storage, 2023, 57: doi: 10.1016/j.est.2022.106181.
46	GUO H, XU Y J, HUANG L J, et al. Optimization strategy using corresponding-point methodology (CPM) concerning finite time and heat conduction rate for CAES systems[J]. Energy, 2023, 266: doi: 10.1016/j.energy.2022.126336.
47	耿晓倩, 徐玉杰, 黄景坚, 等. 先进压缩空气储能系统全生命周期能耗及二氧化碳排放[J]. 储能科学与技术, 2022, 11(9): 2971-2979.
	GENG X Q, XU Y J, HUANG J J, et al. Life cycle energy consumption and carbon emissions of advanced adiabatic compressed air energy storage[J]. Energy Storage Science and Technology, 2022, 11(9): 2971-2979.
48	LIN Z H, ZUO Z T, LI W, et al. Experimental and numerical analysis of the impeller backside cavity in a centrifugal compressor for CAES[J]. Energies, 2022, 15(2): 420.
49	MENG C, ZUO Z T, SUN J T, et al. Numerical study on the influence of shroud cavity in the high-pressure centrifugal compressor for compressed air energy storage system[J]. IOP Conference Series: Earth and Environmental Science, 2021, 804(3): doi: 10.1088/1755-1315/804/3/032018.
50	MENG C, ZUO Z T, SUN J T, et al. Internal inflow study on a high-pressure centrifugal compressor with shroud and backside cavity in a compressed air energy storage system[J]. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, 2022, 236(7): 1418-1432.
51	SUN J T, ZUO Z T, LIANG Q, et al. Theoretical and experimental study on effects of wet compression on centrifugal compressor performance[J]. Applied Thermal Engineering, 2022, 212: doi: 10.1016/j.applthermaleng.2022.118163.
52	MENG C, ZUO Z T, GUO W B, et al. Experimental and numerical investigation on off-design performance of a high-pressure centrifugal compressor in compressed air energy storage system[J]. Journal of Energy Storage, 2022, 53: doi: 10.1016/j.est.2022.105081.
53	LI H Y, LI W, ZHANG X H, et al. Performance and flow characteristics of the liquid turbine for supercritical compressed air energy storage system[J]. Applied Thermal Engineering, 2022, 211: doi: 10.1016/j.applthermaleng.2022.118491.
54	SHAO Z Y, LI W, ZHU Y L, et al. Experimental investigation of intake and leakage performance for a shrouded radial turbine in the compressed air energy storage system[J]. Journal of Energy Storage, 2022, 52: doi: 10.1016/j.est.2022.104875.
55	HUANG G R, ZHU Y L, WANG X, et al. Flow characteristics of last-segment axial turbine adopted in compressed air energy storage system under low load and windage conditions[J]. International Journal of Energy Research, 2022, 46(15): 23908-23926.
56	HU S W, XU W Q, CAI M L, et al. Energy efficiency and power density analysis of a tube array liquid piston air compressor/expander for compressed air energy storage[J]. Journal of Energy Storage, 2022, 55: doi: 10.1016/j.est.2022.105674.
57	李瑞雄, 邹瀚森, 姚尔人, 等. 液体活塞近等温压缩空气储能过程热力性能评估[J/OL]. 西安交通大学学报, 2023(5): 1-10.
58	XIONG J W, PAN X, ZHU Y, et al. Solidity optimization of compressed air energy storage turbine during off-design conditions[C]//2nd World Energy Conference and 7th UK Energy Storage Conference, BIRMINGHAM, UNITED KINGDOM, 2022.
59	QU Y L, WANG L, LIN X P, et al. Heat transfer characteristics of mixed convection in packed beds[J]. Chemical Engineering Science, 2022, 255: doi: 10.1016/j.ces.2022.117679.
60	廖丹, 胡章茂, 王唯, 等. 立方体填充料结构内换热与流动特性[J]. 储能科学与技术, 2023, 12(3): 676-684.
	LIAO D, HU Z M, WANG W, et al. Research on heat transfer and flow characteristics of cubic fillers[J]. Energy Storage Science and Technology, 2023, 12(3): 676-684.
61	张志浩, 靳晓刚, 包恒兴, 等. 混合加热反应器内Ca(OH)₂/CaO热化学储能体系实验[J]. 储能科学与技术, 2023, 12(1): 227-235.
	ZHANG Z H, JIN X G, BAO H X, et al. Experimental study of Ca(OH)2/CaO thermochemical energy storage in a mixed heating reactor[J]. Energy Storage Science and Technology, 2023, 12(1): 227-235.
62	葛刚强, 王焕然, 李瑞雄, 等. 压缩空气储能蓄热器性能分析和优化设计[J]. 西安交通大学学报, 2023, 57(1): 45-54.
	GE G Q, WANG H R, LI R X, et al. Performance analysis and optimization design of heat accumulator in compressed air energy storage[J]. Journal of Xi'an Jiaotong University, 2023, 57(1): 45-54.
63	吴玉庭, 寇真峰, 张灿灿, 等. 列管式固体氯化钠蓄冷换热器动态分布参数分析[J]. 储能科学与技术, 2022, 11(6): 1988-1995.
	WU Y T, KOU Z F, ZHANG C C, et al. Analysis of the dynamic distribution parameters of a solid sodium chloride column heat exchanger[J]. Energy Storage Science and Technology, 2022, 11(6): 1988-1995.
64	HAN Y, CUI H, MA H L, et al. Temperature and pressure variations in salt compressed air energy storage (CAES) Caverns considering the air flow in the underground wellbore[J]. Journal of Energy Storage, 2022, 52: doi: 10.1016/j.est.2022.104846.
65	LI P, CHEN Z G, ZHOU X Z, et al. Temperature regulation model and experimental study of compressed air energy storage cavern heat exchange system[J]. Sustainability, 2022, 14(11): 6788.
66	LI Y, YU H, LUO X, et al. Full cycle modeling of inter-seasonal compressed air energy storage in aquifers[J]. Energy, 2022, 263: doi: 10.1016/j.energy.2022.125987.
67	QIN S K, XIA C C, ZHOU S W. Air tightness of compressed air storage energy Caverns with polymer sealing layer subjected to various air pressures[J]. Journal of Rock Mechanics and Geotechnical Engineering, 2022: doi: 10.1016/j.jrmge.2022.10.007.
68	RAN P, WANG Y, WANG Y S, et al. Thermodynamic, economic and environmental investigations of a novel solar heat enhancing compressed air energy storage hybrid system and its energy release strategies[J]. Journal of Energy Storage, 2022, 55: doi: 10.1016/j.est.2022.105423.
69	XUE X J, LV J Y, CHEN H, et al. Thermodynamic and economic analyses of a new compressed air energy storage system incorporated with a waste-to-energy plant and a biogas power plant[J]. Energy, 2022, 261: doi: 10.1016/j.energy.2022.125367.
70	XUE X J, LU D, LIU Y F, et al. Thermodynamic and economic analysis of new compressed air energy storage system integrated with water electrolysis and H₂-Fueled solid oxide fuel cell[J]. Energy, 2023, 263: doi: 10.1016/j.energy.2022.126114.
71	ZHENG A H, CAO Z, XU Y J, et al. Analysis of hybrid Adiabatic Compressed Air Energy Storage-Reverse Osmosis desalination system with different topological structures[J]. Desalination, 2022, 530: doi: 10.1016/j.desal.2022.115667.
72	李拴魁, 林原, 潘锋. 热能存储及转化技术进展与展望[J]. 储能科学与技术, 2022, 11(5): 1551-1562.
	LI S K, LIN Y, PAN F. Research progress in thermal energy storage and conversion technology[J]. Energy Storage Science and Technology, 2022, 11(5): 1551-1562.
73	姜竹, 邹博杨, 丛琳, 等. 储热技术研究进展与展望[J]. 储能科学与技术, 2022, 11(9): 2746-2771.
	JIANG Z, ZOU B Y, CONG L, et al. Recent progress and outlook of thermal energy storage technologies[J]. Energy Storage Science and Technology, 2022, 11(9): 2746-2771.
74	LÜ H X, FENG D L, FENG Y H, et al. Effect and mechanism of doped graphene nanosheets on phase transition properties of sodium nitrate[J]. Acta Physica Sinica, 2022, 71(15): doi: 10.7498/aps.71.20220354.
75	LYU H X, FENG D L, FENG Y H, et al. Enhanced thermal energy storage of sodium nitrate by graphene nanosheets: Experimental study and mechanisms[J]. Journal of Energy Storage, 2022, 54: doi: 10.1016/j.est.2022.105294.
76	ZHANG S, JIN Y G, YAN Y Y. Depression of melting point and latent heat of molten salts as inorganic phase change material: Size effect and mechanism[J]. Journal of Molecular Liquids, 2022, 346: doi: 10.1016/j.molliq.2021.117058.
77	LIU Y L, DENG Y, ZHENG J L, et al. Micro mechanism of latent heat enhancement of polyethylene glycol/aminated modified palygorskite composite phase change materials[J]. Applied Clay Science, 2022, 228: doi: 10.1016/j.clay.2022.106641.
78	LV L Q, WANG J K, JI M T, et al. Effect of structural characteristics and surface functional groups of biochar on thermal properties of different organic phase change materials: Dominant encapsulation mechanisms[J]. Renewable Energy, 2022, 195: 1238-1252.
79	ZHANG G H, GUO Y Q, ZHANG B, et al. Preparation and control mechanism of nano-phase change emulsion with high thermal conductivity and low supercooling for thermal energy storage[J]. Energy Reports, 2022, 8: 8301-8311.
80	TIAN H Y, TANG J, YUAN S R, et al. The mechanisms study of the effect of sludge hydrolysis residual preparation on the performance of composite phase change materials[J]. Journal of Energy Storage, 2022, 56: doi: 10.1016/j.est.2022.105869.
81	QU Y L, WANG L, LIN X P, et al. Mixed convective heat transfer characteristics and mechanisms in structured packed beds[J]. Particuology, 2023, 82: 122-133.
82	ZHANG S Q, PU L, XU L L, et al. Study on dominant heat transfer mechanism in vertical smooth/finned-tube thermal energy storage during charging process[J]. Applied Thermal Engineering, 2022, 204: doi: 10.1016/j.applthermaleng.2021.117935.
83	WANG Y, ZHU Z L, KE H B, et al. Study of ice spike formation mechanism in the water-based phase change energy storage[J]. Journal of Enhanced Heat Transfer, 2023, 30(1): 53-73.
84	朱娜, 吴涛, 胡平放, 等. 非绝热条件下冰浆管内流动特性研究[J]. 华中科技大学学报(自然科学版), 2022, 50(10): 77-82.
	ZHU N, WU T, HU P F, et al. Research on flow characteristics of ice slurry in pipe under nonadiabatic condition[J]. Journal of Huazhong University of Science and Technology (Natural Science Edition), 2022, 50(10): 77-82.
85	王辉祥, 熊亚选, 任静, 等. Na₂CO₃/电石渣复合相变储热材料制备与性能[J]. 储能科学与技术, 2022, 11(12): 3819-3827.
	WANG H X, XIONG Y X, REN J, et al. Fabrication and performance investigation of Na₂CO₃/Carbide slag shape-stable phase change composites[J]. Energy Storage Science and Technology, 2022, 11(12): 3819-3827.
86	李亚溪, 谭振炜, 李传常. 相变储冷凝胶的制备与应用[J]. 储能科学与技术, 2022, 11(12): 3845-3854.
	LI Y X, TAN Z W, LI C C. Research on the preparation and application of a phase-change gel for cold storage[J]. Energy Storage Science and Technology, 2022, 11(12): 3845-3854.
87	徐运飞, 吴水木, 李英杰. 面向太阳能热发电的CaO-CO₂热化学储热技术研究进展[J]. 发电技术, 2022, 43(5): 740-747.
	XU Y F, WU S M, LI Y J. Research progress of CaO-CO₂ thermochemical heat storage technology for concentrated solar power plant[J]. Power Generation Technology, 2022, 43(5): 740-747.
88	耿直, 张梦琼, 鲁向武, 等. 太阳能蓄热水箱结构优化及储放热性能分析[J]. 热力发电, 2023, 52(2): 64-72.
	GENG Z, ZHANG M Q, LU X W, et al. Structure optimization of solar thermal storage tank and analysis of its thermal storage and release performance[J]. Thermal Power Generation, 2023, 52(2): 64-72.
89	Lin L, Wang L, Bai Y K, et al. Experimental study on the storage performance of the innovative spray-type packed bed thermal energy storage[J]. Applied Thermal Engineering, 2022, 219: doi: 10.1016/j.applthermaleng.2022.119415.
90	周科, 李银龙, 李明皓, 等. 燃煤发电-物理储热耦合技术研究进展与系统调峰能力分析[J]. 洁净煤技术, 2022, 28(3): 159-172.
	ZHOU K, LI Y L, LI M H, et al. Research progress on the coupling technology of coal-fired power generation-physical thermal storage and analysis for the system peaking capacity[J]. Clean Coal Technology, 2022, 28(3): 159-172.
91	张静, 庞志刚, 李乐, 等. 动态冰浆蓄冷空调系统在北京市某恒温恒湿实验室的应用研究[J]. 节能, 2022, 41(11): 11-13.
	ZHANG J, PANG Z G, LI L, et al. Application research of dynamic ice slurry cold storage air conditioning system in a constant temperature and humidity laboratory in Beijing[J]. Energy Conservation, 2022, 41(11): 11-13.
92	周传迪. 大容量储能飞轮转子-支撑系统动力学特性研究[D]. 北京: 华北电力大学(北京), 2022.
93	刘钙. 飞轮储能磁轴承支承系统优化设计及控制研究[D]. 镇江: 江苏大学, 2022.
	LIU G. Research on optimization design and control of magnetic bearings support system for flywheel energy storage[D]. Zhenjiang: Jiangsu University, 2022.
94	CHEN Y G, ZANG B Q. Analysis of alternating flux density harmonics inside the rotor of a 1 MW high-speed interior permanent magnet synchronous machine used for flywheel energy storage systems[J]. Journal of Energy Storage, 2022, 55: doi: 10.1016/j.est.2022.105664.
95	BAO Z, JING H L, LIU W, et al. Performance evaluation of a superconducting flywheel energy storage system incorporating an AC homopolar motor layout[J]. Superconductor Science and Technology, 2022, 35(8): doi: 10.1088/1361-6668/ac7585.
96	刘海山, 徐宪龙, 魏书洲, 等. 基于提升华北电网考核指标的飞轮储能参与调频划分电量控制策略[J]. 储能科学与技术, 2023, 12(4): 1176-1184.
	LIU H S, XU X L, WEI S Z, et al. Flywheel energy storage participates in frequency modulation power division control based on improving power grid assessment index of North China power grid[J]. Energy Storage Science and Technology, 2023, 12(4): 1176-1184.
97	CHEN X D, LI Y, HUAN D J, et al. Influence of filament winding tension on the deformation of composite flywheel rotors with H-shaped hubs[J]. Polymers, 2022, 14(6): 1155.
98	WANG H Z, WU Z G, LIU K, et al. Modeling and control strategies of a novel axial hybrid magnetic bearing for flywheel energy storage system[J]. IEEE/ASME Transactions on Mechatronics, 2022, 27(5): 3819-3829.
99	吕东元, 吕奇超, 李延宝, 等. 磁悬浮储能飞轮高速永磁电机设计及优化[J]. 大电机技术, 2022(2): 6-12, 44.
	LV D Y, LV Q C, LI Y B, et al. The design and optimization of high-speed permanent magnet machines for maglev flywheel energy storage system[J]. Large Electric Machine and Hydraulic Turbine, 2022(2): 6-12, 44.
100	LI Z R, NIE Z L, XU J E, et al. Harmonic analysis and neutral-point potential control of interleaved parallel three-level inverters for flywheel energy storage system[J]. Frontiers in Energy Research, 2022, 9: doi: 10.3389/fenrg.2021.811845.
101	张继红, 刘云飞, 吴振奎, 等. 飞轮与电池混合储能的直流微网母线电压波动抑制策略[J]. 化工自动化及仪表, 2022, 49(6): 699-706.
	ZHANG J H, LIU Y F, WU Z K, et al. Suppression strategy for DC microgrid bus voltage fluctuation of hybrid flywheel and battery energy storage[J]. Control and Instruments in Chemical Industry, 2022, 49(6): 699-706.
102	许庆祥, 滕伟, 武鑫, 等. 平抑风电功率波动的飞轮储能系统容量配置方法[J]. 储能科学与技术, 2022, 11(12): 3906-3914.
	XU Q X, TENG W, WU X, et al. Capacity configuration method of flywheel storage system for suppressing power fluctuation of wind farms[J]. Energy Storage Science and Technology, 2022, 11(12): 3906-3914.
103	罗耀东, 田立军, 王垚, 等. 飞轮储能参与电网一次调频协调控制策略与容量优化配置[J]. 电力系统自动化, 2022, 46(9): 71-82.
	LUO Y D, TIAN L J, WANG Y, et al. Coordinated control strategy and optimal capacity configuration for flywheel energy storage participating in primary frequency regulation of power grid[J]. Automation of Electric Power Systems, 2022, 46(9): 71-82.
104	李彦吉, 陈鹰, 李祎杨. 基于飞轮储能的牵引变电所能量回收和电能质量综合治理系统的设计[J]. 储能科学与技术, 2022, 11(12): 3883-3894.
	LI Y J, CHEN Y, LI Y Y. Design of regenerative braking and power quality harnessed synthetically system in traction substation based on flywheel energy storage[J]. Energy Storage Science and Technology, 2022, 11(12): 3883-3894.
105	李树胜, 王佳良, 李光军, 等. MW级飞轮阵列在风光储能基地示范应用[J]. 储能科学与技术, 2022, 11(2): 583-592.
	LI S S, WANG J L, LI G J, et al. Demonstration applications in wind solar energy storage field based on MW flywheel array system[J]. Energy Storage Science and Technology, 2022, 11(2): 583-592.
106	青岛地铁. 飞轮储能项目: 让青岛城市轨道交通驶入绿色快车道[EB/OL]. (2022-04-25)http://www.qd-metro.com/planning/view.php?id=5565.
107	BOZKAYA B, BAUKNECHT S, SETTELEIN J, et al. Comparison of dynamic charge acceptance tests on lead-acid cells for carbon additive screening[J]. Energy Technology, 2022, 10(4): doi: 10.1002/ente.202101051.
108	YIN J, LIN H, SHI J, et al. Lead-carbon batteries toward future energy storage: from mechanism and materials to applications[J]. Electrochemical Energy Reviews, 2022, 5(3): doi: 10.1007/s41918-022-00134-w.
109	陈理, 王丽, 胡曙, 等. 香兰素在铅炭电池负极中的应用研究[J]. 蓄电池, 2022, 59(5): 246-250.
	CHEN L, WANG L, HU S, et al. Study on the application of vanillin in the negative electrode of lead carbon battery[J]. Chinese LABAT Man, 2022, 59(5): 246-250.
110	YANAMANDRA K, BEHERA R K, DAOUD A, et al. Migration barrier estimation of carbon in lead for lead-acid battery applications: A density functional theory approach[J]. Solids, 2022, 3(2): 177-187.
111	WANG Z D, TUO X P, ZHOU J Q, et al. Performance study of large capacity industrial lead‑carbon battery for energy storage[J]. Journal of Energy Storage, 2022, 55: doi: 10.1016/j.est.2022. 105398.
112	BAUKNECHT S, KOWAL J, BOZKAYA B, et al. The effects of cell configuration and scaling factors on constant current discharge and dynamic charge acceptance in lead-acid batteries[J]. Journal of Energy Storage, 2022, 45: doi: 10.1016/j.est.2021.103667.
113	SHI C G, PENG X X, DAI P, et al. Investigation and suppression of oxygen release by LiNi_0.8Co_0.1Mn_0.1O₂ cathode under overcharge conditions[J]. Advanced Energy Materials, 2022, 12(20): doi: 10.1002/aenm.202200569.
114	WANG D H, MA Y J, XU W Q, et al. Controlled isotropic canalization of microsized silicon enabling stable high-rate and high-loading lithium storage[J]. Advanced Materials, 2023: doi: 10.1002/adma.202212157.
115	YAO Y X, YAO N, ZHOU X R, et al. Ethylene-carbonate-free electrolytes for rechargeable Li-ion pouch cells at sub-freezing temperatures[J]. Advanced Materials, 2022, 34(45): doi: 10. 1002/adma.202206448.
116	BAO C S, ZHENG C J, WU M F, et al. 12 µm-thick sintered garnet ceramic skeleton enabling high-energy-density solid-state lithium metal batteries[J]. Advanced Energy Materials, 2023, 13(13): doi: 10.1002/aenm.202204028.
117	LIN J, FAN E S, ZHANG X D, et al. Sustainable upcycling of spent lithium-ion batteries cathode materials: Stabilization by in situ Li/Mn disorder[J]. Advanced Energy Materials, 2022, 12(26): doi: 10.1002/aenm.202201174.
118	王维坤, 王安邦, 金朝庆. 锂硫电池的实用化挑战[J]. 储能科学与技术, 2020, 9(2): 593-597.
	WANG W K, WANG A B, JIN Z Q. Challenges on practicalization of lithium sulfur batteries[J]. Energy Storage Science and Technology, 2020, 9(2): 593-597.
119	LIU S Q, WANG B Y, ZHANG X, et al. Reviving the lithium-manganese-based layered oxide cathodes for lithium-ion batteries[J]. Matter, 2021, 4(5): 1511-1527.
120	HUA W X, SHANG T X, LI H A, et al. Optimizing the p charge of S in p-block metal sulfides for sulfur reduction electrocatalysis[J]. Nature Catalysis, 2023, 6(2): 174-184.
121	WANG Z Y, GE H L, LIU S, et al. High-entropy alloys to activate the sulfur cathode for lithium-sulfur batteries[J]. Energy & Environmental Materials, 2022: doi: 10.1002/eem2.12358.
122	JI H Q, WANG Z K, SUN Y W, et al. Weakening Li⁺ de-solvation barrier for cryogenic Li-S pouch cells[J]. Advanced Materials, 2023, 35(9): doi: 10.1002/adma.202208590.
123	CHU F L, WANG M, LIU J M, et al. Low concentration electrolyte enabling cryogenic lithium-sulfur batteries[J]. Advanced Functional Materials, 2022, 32(44): doi: 10.1002/adfm.202205393.
124	HUANG L, LU T, XU G J, et al. Thermal runaway routes of large-format lithium-sulfur pouch cell batteries[J]. Joule, 2022, 6(4): 906-922.
125	JI Y C, YANG K, LIU M Q, et al. PIM-1 as a multifunctional framework to enable high-performance solid-state lithium-sulfur batteries[J]. Advanced Functional Materials, 2021, 31(47): doi: 10.1002/adfm.202104830.
126	CHEN J H, LU H C, ZHANG X, et al. Electrochemical polymerization of nonflammable electrolyte enabling fast-charging lithium-sulfur battery[J]. Energy Storage Materials, 2022, 50: 387-394.
127	LIU Y, LIU H W, LIN Y T, et al. Mechanistic investigation of polymer-based all-solid-state lithium/sulfur battery[J]. Advanced Functional Materials, 2021, 31(41): doi: 10.1002/adfm.202104863.
128	PAN H, ZHANG M H, CHENG Z, et al. Carbon-free and binder-free Li-Al alloy anode enabling an all-solid-state Li-S battery with high energy and stability[J]. Science Advances, 2022, 8(15): doi: 10.1126/sciadv.abn4372.
129	ZHU X X, JIANG W, ZHAO S, et al. Exploring the concordant solid-state electrolytes for all-solid-state lithium-sulfur batteries[J]. Nano Energy, 2022, 96: doi: 10.1016/j.nanoen.2022.107093.
130	PANG Q Q, MENG J S, GUPTA S, et al. Fast-charging aluminium-chalcogen batteries resistant to dendritic shorting[J]. Nature, 2022, 608(7924): 704-711.
131	ZHANG D, CHU W Q, WANG D Y, et al. High-voltage aluminium-sulfur batteries with functional polymer membrane[J]. Advanced Functional Materials, 2022, 32(39): doi: 10.1002/adfm.202205562.
132	ZHOU X F, YU Z X, YAO Y, et al. A high-efficiency Mo2C electrocatalyst promoting the polysulfide redox kinetics for Na-S batteries[J]. Advanced Materials, 2022, 34(14): doi: 10.1002/adma.202200479.
133	LI Z, WANG C L, LING F X, et al. Room-temperature sodium-sulfur batteries: Rules for catalyst selection and electrode design[J]. Advanced Materials, 2022, 34(32): doi: 10.1002/adma.202204214.
134	WU J R, TIAN Y, GAO Y F, et al. Rational electrolyte design toward cyclability remedy for room-temperature sodium-sulfur batteries[J]. Angewandte Chemie International Edition, 2022, 61(30): doi: 10.1002/anie.202205416.
135	SU L W, XU Q H, SONG Y, et al. Ce(NO₃)₄: A dual-functional electrolyte additive for room-temperature sodium-sulfur batteries[J]. Chemical Engineering Journal, 2022, 450: doi: 10.1016/j.cej. 2022.137978.
136	ZOU Q L, SUN Y, LIANG Z J, et al. Achieving efficient magnesium-sulfur battery chemistry via polysulfide mediation[J]. Advanced Energy Materials, 2021, 11(31): doi: 10.1002/aenm. 202101552.
137	WU T H, LIU X, ZHANG X, et al. Full concentration gradient-tailored Li-rich layered oxides for high-energy lithium-ion batteries[J]. Advanced Materials, 2021, 33(2): doi: 10.1002/adma.202001358.
138	YU H J, SO Y G, REN Y, et al. Temperature-sensitive structure evolution of lithium-manganese-rich layered oxides for lithium-ion batteries[J]. Journal of the American Chemical Society, 2018, 140(45): 15279-15289.
139	WU T H, ZHANG X, WANG Y Z, et al. Gradient "single-crystal" Li-rich cathode materials for high-stable lithium-ion batteries[J]. Advanced Functional Materials, 2023, 33(4): doi: 10.1002/adfm.202210154.
140	SONG J, NING F H, ZUO Y X, et al. Entropy stabilization strategy for enhancing the local structural adaptability of Li-rich cathode materials[J]. Advanced Materials, 2023, 35(7): doi: 10.1002/adma.202208726.
141	LIU T C, LIU J J, LI L X, et al. Origin of structural degradation in Li-rich layered oxide cathode[J]. Nature, 2022, 606(7913): 305-312.
142	AIKEN C P, LOGAN E R, ELDESOKY A, et al. Li[Ni_0.5Mn_0.3Co_0.2]O₂ as a superior alternative to LiFePO₄ for long-lived low voltage Li-ion cells[J]. Journal of the Electrochemical Society, 2022, 169(5): doi: 10.1149/1945-7111/ac67b5.
143	袁治章, 刘宗浩, 李先锋. 液流电池储能技术研究进展[J]. 储能科学与技术, 2022, 11(9): 2944-2958.
	YUAN Z Z, LIU Z H, LI X F. Research progress of flow battery technologies[J]. Energy Storage Science and Technology, 2022, 11(9): 2944-2958.
144	XIA Y S, CAO H Y, XU F, et al. Polymeric membranes with aligned zeolite nanosheets for sustainable energy storage[J]. Nature Sustainability, 2022, 5(12): 1080-1091.
145	ZHANG Y H, LI F, LI T Y, et al. Insights into an air-stable methylene blue catholyte towards kW-scale practical aqueous organic flow batteries[J]. Energy & Environmental Science, 2023, 16(1): 231-240.
146	LIU Y, XIE C X, LI X F. Bromine assisted MnO₂ dissolution chemistry: Toward a hybrid flow battery with energy density of over 300 Wh L-1[J]. Angewandte Chemie International Edition, 2022, 61(51): doi: 10.1002/anie.202213751.
147	YU D L, ZHI L P, ZHANG F F, et al. Scalable alkaline zinc-iron/nickel hybrid flow battery with energy density up to 200 wh L-1[J]. Advanced Materials, 2023, 35(7): doi: 10.1002/adma.202209390.
148	YUAN Z Z, LIANG L X, DAI Q, et al. Low-cost hydrocarbon membrane enables commercial-scale flow batteries for long-duration energy storage[J]. Joule, 2022, 6(4): 884-905.
149	DING F X, ZHAO C L, XIAO D D, et al. Using high-entropy configuration strategy to design Na-ion layered oxide cathodes with superior electrochemical performance and thermal stability[J]. Journal of the American Chemical Society, 2022, 144(18): 8286-8295.
150	GAO A, ZHANG Q H, LI X Y, et al. Topologically protected oxygen redox in a layered manganese oxide cathode for sustainable batteries[J]. Nature Sustainability, 2021, 5(3): 214-224.
151	FU F, LIU X A, FU X G, et al. Entropy and crystal-facet modulation of P2-type layered cathodes for long-lasting sodium-based batteries[J]. Nature Communications, 2022, 13: doi: 10.1038/s41467-022-30113-0.
152	SHI Q H, QI R J, FENG X C, et al. Niobium-doped layered cathode material for high-power and low-temperature sodium-ion batteries[J]. Nature Communications, 2022, 13: 3205.
153	SHRAER S D, LUCHININ N D, TRUSSOV I A, et al. Development of vanadium-based polyanion positive electrode active materials for high-voltage sodium-based batteries[J]. Nature Communications, 2022, 13: doi: 10.1038/s41467-022-31768-5.
154	XIE F, NIU Y S, ZHANG Q Q, et al. Screening heteroatom configurations for reversible sloping capacity promises high-power Na-ion batteries[J]. Angewandte Chemie International Edition, 2022, 61(11): doi: 10.1002/anie.202116394.
155	CHI X W, ZHANG Y, HAO F, et al. An electrochemically stable homogeneous glassy electrolyte formed at room temperature for all-solid-state sodium batteries[J]. Nature Communications, 2022, 13: doi: 10.1038/s41467-022-30517-y.
156	WANG X E, ZHANG C, SAWCZYK M, et al. Ultra-stable all-solid-state sodium metal batteries enabled by perfluoropolyether-based electrolytes[J]. Nature Materials, 2022, 21(9): 1057-1065.
157	CHEN F F, WANG X E, ARMAND M, et al. Cationic polymer-in-salt electrolytes for fast metal ion conduction and solid-state battery applications[J]. Nature Materials, 2022, 21(10): 1175-1182.
158	SU Y, RONG X H, GAO A, et al. Rational design of a topological polymeric solid electrolyte for high-performance all-solid-state alkali metal batteries[J]. Nature Communications, 2022, 13: 4181.
159	SU Y, RONG X H, LI H, et al. High-entropy microdomain interlocking polymer electrolytes for advanced all-solid-state battery chemistries[J]. Advanced Materials, 2023, 35(1): doi: 10.1002/adma.202209402.
160	LI Y Q, ZHOU Q, WENG S T, et al. Interfacial engineering to achieve an energy density of over 200 Wh kg-1 in sodium batteries[J]. Nature Energy, 2022, 7(6): 511-519.
161	LIU X, LIU C F, XU S H, et al. Porous organic polymers for high-performance supercapacitors[J]. Chemical Society Reviews, 2022, 51(8): 3181-3225.
162	LI K L, LI J P, ZHU Q Z, et al. Three-dimensional MXenes for supercapacitors: A review[J]. Small Methods, 2022, 6(4): doi: 10.1002/smtd.202101537.
163	XING F F, BI Z H, Su F, et al. Unraveling the design principles of battery-supercapacitor hybrid devices: From fundamental mechanisms to microstructure engineering and challenging perspectives[J]. Advanced Energy Materials, 2022, 12(26): doi: 10.1002/aenm.202200594.
164	HE B, ZHANG Q C, PAN Z H, et al. Freestanding metal-organic frameworks and their derivatives: An emerging platform for electrochemical energy storage and conversion[J]. Chemical Reviews, 2022, 122(11): 10087-10125.
165	ZHENG S S, SUN Y, XUE H G, et al. Dual-ligand and hard-soft-acid-base strategies to optimize metal-organic framework nanocrystals for stable electrochemical cycling performance[J]. National Science Review, 2022, 9(7): doi: 10.1093/nsr/nwab197.
166	YANG X X, ZHAO S, ZHANG Z Z, et al. Pore structure regulation of hierarchical porous carbon derived from coal tar pitch via pre-oxidation strategy for high-performance supercapacitor[J]. Journal of Colloid and Interface Science, 2022, 614: 298-309.
167	WANG Q, CHEN Y Y, JIANG X, et al. Self-assembly defect-regulating superstructured carbon[J]. Energy Storage Materials, 2022, 48: 164-171.
168	ZHAO J A, WANG S M, GAO L J, et al. NiO nanoparticles anchored on N-doped laser-induced graphene for flexible planar micro-supercapacitors[J]. ACS Applied Nano Materials, 2022, 5(8): 11314-11323.
169	LIU W J, ZHANG X, XU Y N, et al. 2D graphene/MnO heterostructure with strongly stable interface enabling high-performance flexible solid-state lithium-ion capacitors[J]. Advanced Functional Materials, 2022, 32(30): doi: 10.1002/adfm.202202342.
170	ZHANG T Q, MAO Z, SHI X J, et al. Tissue-derived carbon microbelt paper: A high-initial-coulombic-efficiency and low-discharge-platform K⁺-storage anode for 4.5 V hybrid capacitors[J]. Energy & Environmental Science, 2022, 15(1): 158-168.
171	JIANG Y Q, MA K, SUN M L, et al. All-climate stretchable dendrite-free Zn-ion hybrid supercapacitors enabled by hydrogel electrolyte engineering[J]. Energy & Environmental Materials, 2023, 6(2): doi: 10.1002/eem2.12357.
172	ZHAO Y Z, LIANG Q D, MUGO S M, et al. Self-healing and shape-editable wearable supercapacitors based on highly stretchable hydrogel electrolytes[J]. Advanced Science, 2022, 9(24): doi: 10.1002/advs.202201039.
173	许珂, 陈珏锡, 孟瑶, 等. Cu-NiCoP微球的制备及其超级电容性能[J]. 储能科学与技术, 2023, 12(2): 357-365.
	XU K, CHEN J X, MENG Y, et al. Preparation of Cu-NiCoP microspheres and their supercapacitive performance[J]. Energy Storage Science and Technology, 2023, 12(2): 357-365.
174	TANG P, TAN W Y, LI F Z, et al. A pseudocapacitor diode based on ion-selective surface redox effect[J]. Advanced Materials, 2023, 35(10): doi: 10.1002/adma.202209186.
175	ZHANG X H, SUN X Z, AN Y B, et al. Design of a fast-charge lithium-ion capacitor pack for automated guided vehicle[J]. Journal of Energy Storage, 2022, 48: doi: 10.1016/j.est.2022.104045.
176	ZHU Y Y, ZHENG S H, LU P F, et al. Kinetic regulation of MXene with water-in-LiCl electrolyte for high-voltage micro-supercapacitors[J]. National Science Review, 2022, 9(7): doi: 10.1093/nsr/nwac024.
177	CHI F Y, HU Y J, HE W Y, et al. Graphene ionogel ultra-fast filter supercapacitor with 4 V workable window and 150 ℃ operable temperature[J]. Small, 2022, 18(18): doi: 10.1002/smll.202200916.
178	陈云良, 刘旻, 凡家异, 等. 重力储能发电现状、技术构想及关键问题[J]. 工程科学与技术, 2022, 54(1): 97-105.
	CHEN Y L, LIU M, FAN J Y, et al. Present situation, technology conceptualization and key problem for gravity energy storage[J]. Advanced Engineering Sciences, 2022, 54(1): 97-105.
179	肖立业, 张京业, 聂子攀, 等. 地下储能工程[J]. 电工电能新技术, 2022, 41(2): 1-9.
	XIAO L Y, ZHANG J Y, NIE Z P, et al. Underground energy storage engineering[J]. Advanced Technology of Electrical Engineering and Energy, 2022, 41(2): 1-9.
180	秦婷婷, 周学志, 郭丁彰, 等. 铁轨重力储能系统效率影响因素研究[J]. 储能科学与技术, 2023, 12(3): 835-845.
	QIN T T, ZHOU X Z, GUO D Z, et al. Study on factors influencing rail gravity energy storage system efficiency[J]. Energy Storage Science and Technology, 2023, 12(3): 835-845.
181	TONG W X, LU Z G, CHEN W J, et al. Solid gravity energy storage: A review[J]. Journal of Energy Storage, 2022, 53: doi: 10.1016/j.est.2022.105226.
182	赵永明, 邱清泉, 聂子攀, 等. 重力/飞轮综合储能电机变流并网系统设计及运行特性[J]. 储能科学与技术, 2022, 11(12): 3895-3905.
	ZHAO Y M, QIU Q Q, NIE Z P, et al. Design and operating characteristics of a grid-connected motor-converting system for gravity/flywheel integrated energy storage[J]. Energy Storage Science and Technology, 2022, 11(12): 3895-3905.
183	夏焱, 万继方, 李景翠, 等. 重力储能技术研究进展[J]. 新能源进展, 2022, 10(3): 258-264.
	XIA Y, WAN J F, LI J C, et al. Research progress of gravity energy storage technology[J]. Advances in New and Renewable Energy, 2022, 10(3): 258-264.
184	王柄根. 中国天楹: 重力储能将打开新成长空间[J]. 股市动态分析, 2022(19): 44-45.
	WANG B G. China Tian Ying: Gravity energy storage will open up new growth space[J]. Stock Market Trend Analysis Weekly, 2022(19): 44-45.
185	WANG L, LIN X P, ZHANG H, et al. Thermodynamic analysis and optimization of pumped thermal-liquid air energy storage (PTLAES)[J]. Applied Energy, 2023, 332: doi: 10.1016/j.apenergy.2022.120499.
186	XUE X J, ZHAO C Y. Transient behavior and thermodynamic analysis of Brayton-like pumped-thermal electricity storage based on packed-bed latent heat/cold stores[J]. Applied Energy, 2023, 329: doi: 10.1016/j.apenergy.2022.120274.
187	PANG J S, XU C, WU Y Z, et al. Thermodynamic analysis and parameter optimization of a Chemical Looping Electricity Storage system[J]. Journal of Energy Storage, 2022, 55: doi: 10.1016/j.est.2022.105832.
188	SUN R Q, ZHAO Y L, LIU M, et al. Thermodynamic design and optimization of pumped thermal electricity storage systems using supercritical carbon dioxide as the working fluid[J]. Energy Conversion and Management, 2022, 271: doi: 10.1016/j.enconman.2022.116322.
189	ZHANG H, WANG L, LIN X P, et al. Parametric optimisation and thermo-economic analysis of Joule-Brayton cycle-based pumped thermal electricity storage system under various charging-discharging periods[J]. Energy, 2023, 263: doi: 10.1016/j.energy.2022.125908.
190	ZHAO Y L, SONG J, LIU M, et al. Thermo-economic assessments of pumped-thermal electricity storage systems employing sensible heat storage materials[J]. Renewable Energy, 2022, 186: 431-456.
191	LIU S H, BAI H P, JIANG P, et al. Economic, energy and exergy assessments of a Carnot battery storage system: Comparison between with and without the use of the regenerators[J]. Journal of Energy Storage, 2022, 50: doi: 10.1016/j.est. 2022.104577.
192	FAN R X, XI H. Energy, exergy, economic (3E) analysis, optimization and comparison of different Carnot battery systems for energy storage[J]. Energy Conversion and Management, 2022, 252: doi: 10.1016/j.enconman.2021.115037.
193	FAN R X, XI H. Exergoeconomic optimization and working fluid comparison of low-temperature Carnot battery systems for energy storage[J]. Journal of Energy Storage, 2022, 51: doi: 10.1016/j.est.2022.104453.
194	TIAN W B, XI H. Comparative analysis and optimization of pumped thermal energy storage systems based on different power cycles[J]. Energy Conversion and Management, 2022, 259: doi: 10.1016/j.enconman.2022.115581.
195	ZHANG Y C, XIE Z Z. Thermodynamic efficiency and bounds of pumped thermal electricity storage under whole process ecological optimization[J]. Renewable Energy, 2022, 188: 711-720.
196	ZHAO Y, SONG J, ZHAO C Y, et al. Thermodynamic investigation of latent-heat stores for pumped-thermal energy storage[J]. Journal of Energy Storage, 2022, 55: doi: 10.1016/j.est.2022.105802.
197	SHI X P, HE Q, LU C, et al. Variable load modes and operation characteristics of closed Brayton cycle pumped thermal electricity storage system with liquid-phase storage[J]. Renewable Energy, 2023, 203: 715-730.
198	YANG H, LI J D, GE Z H, et al. Dynamic characteristics and control strategy of pumped thermal electricity storage with reversible Brayton cycle[J]. Renewable Energy, 2022, 198: 1341-1353.
199	YANG H, LI J D, GE Z H, et al. Dynamic performance for discharging process of pumped thermal electricity storage with reversible Brayton cycle[J]. Energy, 2023, 263: doi: 10.1016/j.energy.2022.125930.
200	LU C, SHI X P, HE Q, et al. Dynamic modeling and numerical investigation of novel pumped thermal electricity storage system during startup process[J]. Journal of Energy Storage, 2022, 55: doi: 10.1016/j.est.2022.105409.
201	XUE X J, ZHAO Y, ZHAO C Y. Multi-criteria thermodynamic analysis of pumped-thermal electricity storage with thermal integration and application in electric peak shaving of coal-fired power plant[J]. Energy Conversion and Management, 2022, 258: doi: 10.1016/j.enconman.2022.115502.
202	李乐璇, 徐玉杰, 尹钊, 等. 超临界二氧化碳储能系统(火用)损特性分析[J]. 储能科学与技术, 2021, 10(5): 1824-1834.
	LI L X, XU Y J, YIN Z, et al. Exergy destruction characteristics of a supercritical carbon-dioxide energy storage system[J]. Energy Storage Science and Technology, 2021, 10(5): 1824-1834.
203	WU C, WAN Y K, LIU Y, et al. Thermodynamic simulation and economic analysis of a novel liquid carbon dioxide energy storage system[J]. Journal of Energy Storage, 2022, 55: doi: 10.1016/j.est.2022.105544.
204	SUN L, TANG B, XIE Y H. Performance assessment of two compressed and liquid carbon dioxide energy storage systems: Thermodynamic, exergoeconomic analysis and multi-objective optimization[J]. Energy, 2022, 256: doi: 10.1016/j.energy. 2022.124648.
205	LU C, HE Q, HAO Y P, et al. Thermodynamic analysis and efficiency improvement of trans-critical compressed carbon dioxide energy storage system[J]. Journal of Energy Storage, 2022, 55: doi: 10.1016/j.est.2022.105480.
206	LIU Z, LIU X, ZHANG W F, et al. Thermodynamic analysis on the feasibility of a liquid energy storage system using CO₂-based mixture as the working fluid[J]. Energy, 2022, 238: doi: 10.1016/j.energy.2021.121759.
207	陶飞跃, 王焕然, 李瑞雄, 等. 利用环境再冷的二氧化碳储能热电联产系统及其热力学分析[J]. 储能科学与技术, 2022, 11(5): 1492-1501.
	TAO F Y, WANG H R, LI R X, et al. Thermodynamic analysis of a combined heating and power system coupled with carbon dioxide energy storage utilizing environmental recooling[J]. Energy Storage Science and Technology, 2022, 11(5): 1492-1501.
208	ZHAO P, ZHANG S Q, XU W P, et al. Performance analysis of a pumped hydro assisted near-isothermal compressed carbon dioxide energy storage system with gas/liquid phase change process[J]. International Journal of Energy Research, 2022, 46(10): 13711-13725.
209	ZHANG T H, GAO J M, ZHANG Y, et al. Thermodynamic analysis of a novel adsorption-type trans-critical compressed carbon dioxide energy storage system[J]. Energy Conversion and Management, 2022, 270: doi: 10.1016/j.enconman.2022. 116268.
210	TANG B, SUN L, XIE Y H. Comprehensive performance evaluation and optimization of a liquid carbon dioxide energy storage system with heat source[J]. Applied Thermal Engineering, 2022, 215: doi: 10.1016/j.applthermaleng.2022.118957.
211	XU W P, ZHAO P, GOU F F, et al. A combined heating and power system based on compressed carbon dioxide energy storage with carbon capture: Exploring the technical potential[J]. Energy Conversion and Management, 2022, 260: doi: 10.1016/j.enconman.2022.115610.
212	JAE C Y, IK L J. Thermodynamic analysis of compressed and liquid carbon dioxide energy storage system integrated with steam cycle for flexible operation of thermal power plant[J]. Energy Conversion and Management, 2022, 256: doi: 10.1016/j.enconman.2022.115374.
213	ZHANG Y, LIANG T Y, YANG K. An integrated energy storage system consisting of Compressed Carbon dioxide energy storage and Organic Rankine Cycle: Exergoeconomic evaluation and multi-objective optimization[J]. Energy, 2022, 247: doi: 10.1016/j.energy.2022.123566.
214	FU H L, HE Q, SONG J T, et al. Thermodynamic of a novel solar heat storage compressed carbon dioxide energy storage system[J]. Energy Conversion and Management, 2021, 247: doi: 10.1016/j.enconman.2021.114757.
215	QI M, PARK J, LANDON R S, et al. Continuous and flexible Renewable-Power-to-Methane via liquid CO₂ energy storage: Revisiting the techno-economic potential[J]. Renewable and Sustainable Energy Reviews, 2022, 153: doi: 10.1016/j.rser.2021.111732.
216	QI M, LEE J, HONG S, et al. Flexible and efficient renewable-power-to-methane concept enabled by liquid CO₂ energy storage: Optimization with power allocation and storage sizing[J]. Energy, 2022, 256: doi: 10.1016/j.energy.2022.124583.
217	HUANG R, ZHOU K, LIU Z. Reduction on the inefficiency of heat recovery storage in a compressed carbon dioxide energy storage system[J]. Energy, 2022, 244: doi: 10.1016/j.energy. 2022.123224.
218	WANG J, YAN X P, LU M J, et al. Structural assessment of printed circuit heat exchangers in supercritical CO₂ waste heat recovery systems for ship applications[J]. Journal of Thermal Science, 2022, 31(3): 689-700.
219	STANEK B, OCHMANN J, BARTELA Ł, et al. Isobaric tanks system for carbon dioxide energy storage-The performance analysis[J]. Journal of Energy Storage, 2022, 52: doi: 10.1016/j.est.2022.104826.
220	李恺. 基于超临界二氧化碳布雷顿循环的塔式太阳能热发电系统设计与研究[D]. 兰州: 兰州交通大学, 2022.
	LI K. Design and research of tower solar thermal power generation system based on supercritical carbon dioxide brayton cycle[D].Lanzhou: Lanzhou Jiatong University, 2022.
221	LI Y, YU H, TANG D, et al. A comparison of compressed carbon dioxide energy storage and compressed air energy storage in aquifers using numerical methods[J]. Renewable Energy, 2022, 187: 1130-1153.
222	韩中合, 孙烨, 李鹏, 等. 压缩空气/二氧化碳储能系统的运行方式研究[J]. 太阳能学报, 2022, 43(3): 119-125.
	HAN Z H, SUN Y, LI P, et al. Research on operation mode of compressed air/carbon dioxide energy storage system[J]. Acta Energiae Solaris Sinica, 2022, 43(3): 119-125.
223	严晓生, 王小东, 韩旭, 等. 液态压缩二氧化碳储能与火电机组耦合方案研究[J]. 热力发电, 2023, 52(2): 90-100.
	YAN X S, WANG X D, HAN X, et al. Study on coupling scheme of liquid compressed carbon dioxide energy storage system and thermal power unit[J]. Thermal Power Generation, 2023, 52(2): 90-100.
224	ZHANG Y, WU Y T, YANG K. Dynamic characteristics of a two-stage compression and two-stage expansion Compressed Carbon dioxide energy storage system under sliding pressure operation[J]. Energy Conversion and Management, 2022, 254: doi: 10.1016/j.enconman.2022.115218.
225	王迪, 司龙, 谢欣言, 等. 耦合超临界二氧化碳储能循环燃煤机组动态特性仿真[J]. 中国电机工程学报, 2023, 43(6): 2142-2153.
	WANG D, SI L, XIE X Y, et al. Simulation of dynamic characteristics of coal-fired unit coupled with supercritical carbon dioxide energy storage cycle[J]. Proceedings of the CSEE, 2023, 43(6): 2142-2153.
226	YAN S, ZHOU X B, LI H M, et al. Utilizing in situ alloying reaction to achieve the self-healing, high energy density and cost-effective Li\|\|Sb liquid metal battery[J]. Journal of Power Sources, 2021, 514: doi: 10.1016/j.jpowsour.2021.230578.
227	ZHOU H, LI H M, GONG Q, et al. A sodium liquid metal battery based on the multi-cationic electrolyte for grid energy storage[J]. Energy Storage Materials, 2022, 50: 572-579.
228	ZHOU Y, LI G Q, LI B X, et al. Operando formation of multi-channel positive electrode achieved via tellurium alloying in liquid metal battery[J]. Energy Storage Materials, 2022, 53: 927-936.
229	LI W M, SHI H, DU K F, et al. Revealing the phase evolution and lithium diffusion in the liquid Sn-Sb electrode[J]. Journal of Electroanalytical Chemistry, 2021, 901: doi: 10.1016/j.jelechem. 2021.115719.
230	LI W M, SHI H, DU K F, et al. Modeling the mass transfer and phase transition of Sn-Sb positive electrode in a liquid metal battery[J]. Journal of Electroanalytical Chemistry, 2022, 909: doi: 10.1016/j.jelechem.2022.116144.
231	JIANG Y D, ZHANG D H, SHI Y X, et al. Lithium transport and intermetallic generation in Li-Bi liquid metal batteries[J]. Electrochimica Acta, 2021, 405: doi.org/10.1016/j.electacta. 2021.139779.
232	ZHOU X B, GAO C L, SHEN Y, et al. Multi-field coupled model for liquid metal battery: Comparative analysis of various flow mechanisms and their effects on mass transfer and electrochemical performance[J]. Energy Reports, 2022, 8: 5510-5521.
233	ZHOU X B, ZHOU H, YAN S, et al. Increasing the actual energy density of Sb-based liquid metal battery[J]. Journal of Power Sources, 2022, 534: doi: 10.1016/j.jpowsour.2022.231428.
234	JIA M Y, CHEN F, WU Y Q, et al. Microstructure and shear fracture behavior of Mo/AlN/Mo symmetrical compositionally graded materials[J]. Materials Science and Engineering: A, 2022, 834: doi: 10.1016/j.msea.2021.142591.
235	SHI Q L, GUO Z L, WANG S, et al. Physics-based fractional-order model and parameters identification of liquid metal battery[J]. Electrochimica Acta, 2022, 428: doi: 10.1016/j.electacta.2022. 140916.
236	SEEL J A, DAHN J R. Electrochemical intercalation of PF₆ into graphite[J]. Journal of the Electrochemical Society, 2000, 147(3): 892.
237	YANG K, LIU Q R, ZHENG Y P, et al. Locally ordered graphitized carbon cathodes for high-capacity dual-ion batteries[J]. Angewandte Chemie International Edition, 2021, 60(12): 6326-6332.
238	JIANG H Z, HAN X Q, DU X F, et al. A PF6-permselective polymer electrolyte with anion solvation regulation enabling long-cycle dual-ion battery[J]. Advanced Materials, 2022, 34(9): doi: 10.1002/adma.202108665.
239	SUN Z Q, ZHU K J, LIU P, et al. Fluorination treatment of conjugated protonated polyanilines for high-performance sodium dual-ion batteries[J]. Angewandte Chemie International Edition, 2022, 61(42): doi: 10.1002/anie.202211866.
240	TONG X Y, OU X W, WU N Z, et al. Dual-ion batteries: High oxidation potential≈6.0V of concentrated electrolyte toward high-performance dual-ion battery[J]. Advanced Energy Materials, 2021, 11(25): doi: 10.1002/aenm.202170096.
241	WANG B Y, HUANG Y H, WANG Y, et al. Synergistic solvation of anion: An effective strategy toward economical high-performance dual-ion battery[J]. Advanced Functional Materials, 2023, 33(12): doi: 10.1002/adfm.202212287.
242	CHENG Z J, GUO L F, DONG Q Y, et al. Highly durable and ultrafast cycling of dual-ion batteries via in situ construction of cathode-electrolyte interphase[J]. Advanced Energy Materials, 2022, 12(44): doi: 10.1002/aenm.202202253.
243	LV S Y, FANG T M, DING Z Z, et al. A high-performance quasi-solid-state aqueous zinc-dual halogen battery[J]. ACS Nano, 2022, 16(12): 20389-20399.
244	LI J, HAN C J, OU X W, et al. Concentrated electrolyte for high-performance Ca-ion battery based on organic anode and graphite cathode[J]. Angewandte Chemie International Edition, 2022, 61(14): doi: 10.1002/anie.202116668.
245	SHENG M H, ZHANG F, JI B F, et al. A novel tin-graphite dual-ion battery based on sodium-ion electrolyte with high energy density[J]. Advanced Energy Materials, 2017, 7(7): doi: 10. 1002/aenm.201601963.
246	JI B F, ZHANG F, SONG X H, et al. A novel potassium-ion-based dual-ion battery[J]. Advanced Materials, 2017, 29(19): doi: 10.1002/adma.201700519.
247	ZHANG X L, TANG Y B, ZHANG F, et al. A novel aluminum-graphite dual-ion battery[J]. Advanced Energy Materials, 2016, 6(11): doi: 10.1002/aenm.201502588.
248	WANG M, JIANG C L, ZHANG S Q, et al. Reversible calcium alloying enables a practical room-temperature rechargeable calcium-ion battery with a high discharge voltage[J]. Nature Chemistry, 2018, 10(6): 667-672.
249	WANG H T, WANG C, ZHANG F, et al. Homogeneous alloying reaction via self-assembly strategy for high-areal-density dual-ion batteries[J]. Chemical Engineering Journal, 2022, 449: doi.org/10.1016/j.cej.2022.137708.
250	YANG X R, NI Y X, LU Y, et al. Designing quinone-based anodes with rapid kinetics for rechargeable proton batteries[J]. Angewandte Chemie International Edition, 2022, 61(39): doi: 10.1002/anie.202209642.
251	CHEN Q L, LI L H, WANG W M, et al. Thiuram monosulfide with ultrahigh redox activity triggered by electrochemical oxidation[J]. Journal of the American Chemical Society, 2022, 144(41): 18918-18926.
252	XU X Y, ZHANG S Q, XU K, et al. Janus dione-based conjugated covalent organic frameworks with high conductivity as superior cathode materials[J]. Journal of the American Chemical Society, 2023, 145(2): 1022-1030.
253	凌志斌, 黄中, 田凯. 大容量电池储能系统技术现状与发展[J]. 供用电, 2018, 35(9): 3-8, 21.
	LING Z B, HUANG Z, TIAN K. The state of art and trend of large scale battery energy storage system technology[J]. Distribution & Utilization, 2018, 35(9): 3-8, 21.
254	杨世春, 李强伟, 周思达, 等. 面向智能化管理的数字孪生电池构建方法[J]. 北京航空航天大学学报, 2022, 48(9): 1734-1744.
	YANG S C, LI Q W, ZHOU S D, et al. Construction of digital twin model of lithium-ion battery for intelligent management[J]. Journal of Beijing University of Aeronautics and Astronautics, 2022, 48(9): 1734-1744.
255	李建林, 方知进, 李雅欣, 等. 用于应急的移动储能系统集群协同控制综述[J]. 电力建设, 2022, 43(3): 75-82.
	LI J L, FANG Z J, LI Y X, et al. Overview of cluster cooperative control of mobile energy storage system for emergency response[J]. Electric Power Construction, 2022, 43(3): 75-82.
256	侯涛. 辅助新型电力系统调频的电化学储能控制策略[D]. 吉林: 东北电力大学, 2022.
	HOU T. Electrochemical energy storage control strategy for assisting frequency modulation of new power system[D]. Jilin: Northeast Dianli University, 2022.
257	杨静, 林振康, 汤君, 等. 电池系统的故障特征以及多故障的诊断与识别[J]. 化工学报, 2022, 73(8): 3394-3405.
	YANG J, LIN Z K, TANG J, et al. A review of fault characteristics, fault diagnosis and identification for lithium-ion battery systems[J]. CIESC Journal, 2022, 73(8): 3394-3405.
258	刘伯峥, 曹六阳, 曾涛, 等. 束缚力对磷酸铁锂电池安全性影响[J]. 储能科学与技术, 2022, 11(8): 2556-2563.
	LIU B Z, CAO L Y, ZENG T, et al. Effect of the binding force on the safety of LiFePO₄ cells[J]. Energy Storage Science and Technology, 2022, 11(8): 2556-2563.
259	JIA Z Z, SONG L F, MEI W X, et al. The preload force effect on the thermal runaway and venting behaviors of large-format prismatic LiFePO₄ batteries[J]. Applied Energy, 2022, 327: doi: 10.1016/j.apenergy.2022.120100.
260	ZHAI H J, CHI M S, LI J Y, et al. Thermal runaway propagation in large format lithium ion battery modules under inclined ceilings[J]. Journal of Energy Storage, 2022, 51: doi: 10.1016/j.est.2022.104477.
261	程志翔, 曹伟, 户波, 等. 储能用大容量磷酸铁锂电池热失控行为及燃爆传播特性[J]. 储能科学与技术, 2023, 12(3): 923-933.
	CHENG Z X, CAO W, HU B, et al. Thermal runaway and explosion propagation characteristics of large lithium iron phosphate battery for energy storage station[J]. Energy Storage Science and Technology, 2023, 12(3): 923-933.
262	SUN H L, ZHANG L, DUAN Q L, et al. Experimental study on suppressing thermal runaway propagation of lithium-ion batteries in confined space by various fire extinguishing agents[J]. Process Safety and Environmental Protection, 2022, 167: 299-307.
263	LIU Y J, YANG K, ZHANG M J, et al. The efficiency and toxicity of dodecafluoro-2-methylpentan-3-one in suppressing lithium-ion battery fire[J]. Journal of Energy Chemistry, 2022, 65: 532-540.
264	WANG W H, HE S, HE T F, et al. Suppression behavior of water mist containing compound additives on lithium-ion batteries fire[J]. Process Safety and Environmental Protection, 2022, 161: 476-487.
265	陆剑心, 张英, 马出原, 等. 水凝胶对磷酸铁锂电池灭火实验性能[J]. 储能科学与技术, 2022, 11(8): 2637-2644.
	LU J X, ZHANG Y, MA C Y, et al. Study on fire-extinguishing performance of hydrogel on lithium-iron-phosphate batteries[J]. Energy Storage Science and Technology, 2022, 11(8): 2637-2644.
266	郭东亮, 郭鹏宇, 孙磊, 等. 细水雾对磷酸铁锂储能电池模组性能影响研究[J]. 消防科学与技术, 2022, 41(8): 1093-1097.
	GUO D L, GUO P Y, SUN L, et al. Research on the influence of water mist on the performance of lithium iron phosphate energy storage battery modules[J]. Fire Science and Technology, 2022, 41(8): 1093-1097.
267	YUAN S, CHANG C Y, ZHOU Y, et al. The extinguishment mechanisms of a micelle encapsulator F-500 on lithium-ion battery fires[J]. Journal of Energy Storage, 2022, 55: doi: 10.1016/j.est.2022.105186.
268	ZHANG F R, LIU P W, HE Y X, et al. Cooling performance optimization of air cooling lithium-ion battery thermal management system based on multiple secondary outlets and baffle[J]. Journal of Energy Storage, 2022, 52: doi: 10.1016/j.est.2022.104678.
269	ZUO S G, CHEN S P, YIN B. Performance analysis and improvement of lithium-ion battery thermal management system using mini-channel cold plate under vibration environment[J]. International Journal of Heat and Mass Transfer, 2022, 193: doi: 10.1016/j.ijheatmasstransfer.2022.122956.
270	LI X T, ZHOU Z Y, ZHANG M J, et al. A liquid cooling technology based on fluorocarbons for lithium-ion battery thermal safety[J]. Journal of Loss Prevention in the Process Industries, 2022, 78: doi: 10.1016/j.jlp.2022.104818.
271	YI F, JIAQIANG E, ZHANG B, et al. Effects analysis on heat dissipation characteristics of lithium-ion battery thermal management system under the synergism of phase change material and liquid cooling method[J]. Renewable Energy, 2022, 181: 472-489.
272	CHEN X, ZHOU F, YANG W, et al. A hybrid thermal management system with liquid cooling and composite phase change materials containing various expanded graphite contents for cylindrical lithium-ion batteries[J]. Applied Thermal Engineering, 2022, 200: doi: 10.1016/j.applthermaleng.2021.117702.
273	OUYANG T C, LIU B L, WANG C C, et al. Novel hybrid thermal management system for preventing Li-ion battery thermal runaway using nanofluids cooling[J]. International Journal of Heat and Mass Transfer, 2023, 201: doi: 10.1016/j.ijheatmasstransfer. 2022.123652.
274	REN R Y, ZHAO Y H, DIAO Y H, et al. Experimental study on preheating thermal management system for lithium-ion battery based on U-shaped micro heat pipe array[J]. Energy, 2022, 253: doi: 10.1016/j.energy.2022.124178.
275	SONG Y H, LYU N W, SHI S, et al. Safety warning for lithium-ion batteries by module-space air-pressure variation under thermal runaway conditions[J]. Journal of Energy Storage, 2022, 56: doi: 10.1016/j.est.2022.105911.
276	ZHANG W C, OUYANG N, YIN X X, et al. Data-driven early warning strategy for thermal runaway propagation in Lithium-ion battery modules with variable state of charge[J]. Applied Energy, 2022, 323: doi: 10.1016/j.apenergy.2022.119614.
277	JI C W, ZHANG Z Z, WANG B, et al. Study on thermal runaway warning method of lithium-ion battery[J]. Journal of Loss Prevention in the Process Industries, 2022, 78: doi: 10.1016/j.jlp.2022.104785.
278	LIAO Z H, ZHANG J G, GAN Z Y, et al. Thermal runaway warning of lithium-ion batteries based on photoacoustic spectroscopy gas sensing technology[J]. International Journal of Energy Research, 2022, 46(15): 21694-21702.
279	ZHOU Z Z, ZHOU X D, LI M Y, et al. Experimentally exploring prevention of thermal runaway propagation of large-format prismatic lithium-ion battery module[J]. Applied Energy, 2022, 327: doi: 10.1016/j.apenergy.2022.120119.
280	CAO J H, LING Z Y, LIN S, et al. Thermochemical heat storage system for preventing battery thermal runaway propagation using sodium acetate trihydrate/expanded graphite[J]. Chemical Engineering Journal, 2022, 433: doi: 10.1016/j.cej.2021.133536.
281	WANG Z R, WANG K H, WANG J L, et al. Inhibition effect of liquid nitrogen on thermal runaway propagation of lithium ion batteries in confined space[J]. Journal of Loss Prevention in the Process Industries, 2022, 79: doi.org/10.1016/j.jlp.2022.104853.
282	HUANG Z H, ZHANG Y, SONG L F, et al. Preventing effect of liquid nitrogen on the thermal runaway propagation in 18650 lithium ion battery modules[J]. Process Safety and Environmental Protection, 2022, 168: 42-53.
283	MENG X D, LI S, FU W D, et al. Experimental study of intermittent spray cooling on suppression for lithium iron phosphate battery fires[J]. eTransportation, 2022, 11: doi: 10.1016/j.etran. 2021.100142.
284	赵光金, 胡玉霞, 李博文, 等. 簇或舱级释放全氟己酮对磷酸铁锂电池的灭火效果[J/OL]. 安全与环境学报: 1-10[2023-05-08]. https://doi.org/10.13637/j.issn.1009-6094.2022.1974.

[1]	吴毅, 孟亚宏, 张怡, 周铁, 刘继, 魏业文. 配电台区电池储能系统优化均衡控制研究[J]. 储能科学与技术, 2023, 12(5): 1655-1663.
[2]	于会群, 胡哲豪, 彭道刚, 孙浩益. 退役动力电池回收及其在储能系统中梯次利用关键技术[J]. 储能科学与技术, 2023, 12(5): 1675-1685.
[3]	李斌, 叶季蕾, 张宇, 时珊珊, 王皓靖, 刘丽丽, 李明哲. 含分布式新能源和机电混合储能接入的微网协调控制策略[J]. 储能科学与技术, 2023, 12(5): 1510-1515.
[4]	李兵, 周洪, 王丽平, 冯晗. 全球储能领域高水平基础研究人才结构特征和研究主题分析[J]. 储能科学与技术, 2023, 12(5): 1738-1746.
[5]	朱璟, 申晓宇, 岑官骏, 乔荣涵, 郝峻丰, 季洪祥, 田孟羽, 金周, 詹元杰, 武怿达, 闫勇, 贲留斌, 俞海龙, 刘燕燕, 黄学杰. 锂电池百篇论文点评（2023.2.1—2023.3.31）[J]. 储能科学与技术, 2023, 12(5): 1553-1569.
[6]	刘家亮, 郭翠静, 汪奂伶. 基于火灾事故树模型的储能锂离子电池安全性检测方法与验证[J]. 储能科学与技术, 2023, 12(5): 1695-1704.
[7]	黄渭彬, 张彪, 范金成, 杨伟, 邹汉波, 陈胜洲. ZIF-8复合PEO基固态电解质的制备与改性研究[J]. 储能科学与技术, 2023, 12(4): 1083-1092.
[8]	张玮灵, 古含, 章超, 葛昂, 应元旭. 压缩空气储能技术经济特点及发展趋势[J]. 储能科学与技术, 2023, 12(4): 1295-1301.
[9]	武鸿鑫, 李爱魁, 董存, 孙树敏, 李广磊, 王士柏. 计及调频备用的储能平抑风电功率波动控制策略[J]. 储能科学与技术, 2023, 12(4): 1194-1203.
[10]	杨妮, 苏岳锋, 王联, 李宁, 马亮, 朱晨. 聚焦离子束显微镜技术在锂离子电池领域的研究进展[J]. 储能科学与技术, 2023, 12(4): 1283-1294.
[11]	管敏渊, 沈建良, 徐国华, 汤舜, 张炜鑫, 曹元成. 锂离子电池储能系统靶向消防装备设计与性能[J]. 储能科学与技术, 2023, 12(4): 1131-1138.
[12]	郭霄宇, 于浩, 郑新, 刘雨佳, 左元杰, 张苗苗. 光伏系统液流电池储能优化配置[J]. 储能科学与技术, 2023, 12(4): 1158-1167.
[13]	刘海山, 徐宪龙, 魏书洲, 逄亚蕾, 洪烽. 基于提升华北电网考核指标的飞轮储能参与调频划分电量控制策略[J]. 储能科学与技术, 2023, 12(4): 1176-1184.
[14]	董文哲, 杨斯泐, 梁宗佑, 陈垠宇. 集成混合储能及RPC的牵引供电系统优化运行[J]. 储能科学与技术, 2023, 12(4): 1185-1193.
[15]	刘子豪, 张雪松, 林达, 孙立清, 李正阳, 熊瑞. 基于扩展卡尔曼滤波的储能电池能量和功率状态联合估计方法[J]. 储能科学与技术, 2023, 12(3): 913-922.

2022年中国储能技术研究进展

Research progress on energy storage technologies of China in 2022

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

图/表 11

参考文献 284

相关文章 15

编辑推荐

Metrics

本文评价