2021年中国储能技术研究进展

doi:10.19799/j.cnki.2095-4239.2022.0105

储能科学与技术 ›› 2022, Vol. 11 ›› Issue (3): 1052-1076.doi: 10.19799/j.cnki.2095-4239.2022.0105

2021年中国储能技术研究进展

陈海生¹(), 李泓²(), 马文涛³, 徐玉杰¹(), 王志峰⁴(), 陈满⁵(), 胡东旭^1,⁶(), 李先锋⁷(), 唐西胜⁴(), 胡勇胜²(), 马衍伟⁴(), 蒋凯⁸(), 钱昊⁹(), 王青松¹⁰(), 王亮¹, 张新敬¹, 王星¹, 徐德厚¹¹, 周学志¹, 刘为¹², 吴贤章¹³, 汪东林¹⁴, 和庆钢¹⁵, 马紫峰¹⁶, 陆雅翔², 张雪松⁴, 李泉², 索鎏敏², 郭欢¹, 俞振华¹², 梅文昕¹⁰, 秦鹏¹⁰

^1.中国科学院工程热物理研究所，北京 100190
^2.中国科学院物理研究所，北京 100190
^3.中国科学院重大科技任务局，北京 100864
^4.中国科学院电工研究所，北京 100190
^5.南方电网调峰调频发电有限公司，广东广州 510623
^6.中国科学院大学，北京 100049
^7.中国科学院大连化学物理研究所，辽宁大连 116023
^8.华中科技大学，湖北武汉 430074
^9.北京海博思创科技股份有限公司，北京 100094
^10.中国科学技术大学火灾科学国家重点实验室，安徽合肥 230026
^11.国家能源大规模物理储能技术研发中心，贵州毕节 551712
^12.中关村储能产业与技术联盟，北京 100190
^13.浙江南都电源动力股份有限公司，浙江临安 310030
^14.阳光电源股份有限公司，安徽合肥 230088；15浙江大学化学工程与生物工程学院
^1.浙江杭州 310027
^6.上海交通大学，上海 200240

收稿日期:2022-02-26 出版日期:2022-03-05 发布日期:2022-03-11
通讯作者: 陈海生,李泓,马文涛,徐玉杰,王志峰,陈满,胡东旭,李先锋,唐西胜,胡勇胜,马衍伟,蒋凯,钱昊,王青松 E-mail:chen_hs@mail.etp.ac.cn;hli@iphy.ac.cn;xuyujie@iet.cn;Zhifeng@vip.sina.com;13926159826@139.com;@139.com;hudongxu@iet.cn;lixianfeng@dicp.ac.cn;tang@mail.iee.ac.cn;yshu@aphy.iphy.ac.cn;ywma@mail.iee.ac.cn;kjiang@hust.edu.cn;qianhhao@hyperstrong.com.cn;pinew@ustc.edu.cn
作者简介:陈海生（1977—），男，研究员，研究方向为新型压缩空气储能系统、超临界流体储能系统、微型燃气轮机，E-mail：chen_hs@mail.etp.ac.cn|李泓，研究员，研究方向为锂离子电池、固态锂电池、失效分析，E-mail：hli@iphy.ac.cn|马文涛，工程师|徐玉杰，研究员，研究方向为压缩空气储能，E-mail：xuyujie@iet.cn|王志峰，研究员，研究方向为太阳能热发电技术、太阳能建筑技术，E-mail：Zhifeng@vip.sina.com|陈满，高级工程师，E-amil：13926159826@139.com|胡东旭，工程师，研究方向为压缩空气储能、飞轮储能、转子动力学、结构强度，E-mail：hudongxu@iet.cn|李先锋，研究员，研究方向为液流电池关键材料与核心技术、模拟及系统结构设计与模拟仿真、检测与评价、创新型电池关键材料与技术等，E-mail：lixianfeng@dicp.ac.cn|唐西胜，研究员，研究方向为分布式电力与储能、微电网和智能电网等，E-mail：tang@mail.iee.ac.cn|胡勇胜，研究员，研究方向为新能源材料与器件及其相关基础科学问题，E-mail：yshu@aphy.iphy.ac.cn|马衍伟，研究员，研究方向为超导与纳米储能材料及器件，E-mail：ywma@mail.iee.ac.cn|蒋凯，教授，研究方向为先进能源材料、新型电化学储能技术、规模储能技术应用，E-mail：kjiang@hust.edu.cn|钱昊，正高级工程师，E-mail：qianhhao@hyperstrong.com.cn|王青松，研究员，研究方向为锂离子电池安全，E-mail：pinew@ustc.edu.cn。
基金资助:
国家杰出青年科学基金项目(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 of energy storage technology in China in 2021

Haisheng CHEN¹(), Hong LI²(), Wentao MA³, Yujie XU¹(), Zhifeng WANG⁴(), Man CHEN⁵(), Dongxu HU^1,⁶(), Xianfeng LI⁷(), Xisheng TANG⁴(), Yongsheng HU²(), Yanwei MA⁴(), Kai JIANG⁸(), Hao QIAN⁹(), Qingsong WANG¹⁰(), Liang WANG¹, Xinjing ZHANG¹, Xing WANG¹, Dehou XU¹¹, Xuezhi ZHOU¹, Wei LIU¹², Xianzhang WU¹³, Donglin WANG¹⁴, Qinggang HE¹⁵, Zifeng MA¹⁶, Yaxiang LU², Xuesong ZHANG⁴, Quan LI², Liumin SUO², Huan GUO¹, Zhenhua YU¹², Wenxin MEI¹⁰, Peng QIN¹⁰

^1.Institute of Engineering Thermophysics, Chinese Academy of Sciences, Beijing 100190, China
^2.Institute of Physics, Chinese Academy of Sciences, Beijing 100190, China
^3.Burea of Major R&D Programs Chinese Academy of Scicences, Beijing 100864, China
^4.Institute of Electrical Engineering Chinese Academy of Sciences, Beijing 100190, China
^5.China Southern Power Grid, Guangzhou 510623, Guangdong, China
^6.Chinese Academy of Sciences, Beijing 100049, China
^7.Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian 116023, Liaoning, China
^8.Huazhong University of Science and Technology, Wuhan 430074, Hubei, China
^9.Beijing Hyper Strong Technology Co. Ltd. , Beijing 10094, China
^10.State Key Laboratory of Fire Science, University of Science and Technology of China, Hefei 230026, Anhui, China
^11.National Energy Large Scale Physical Energy Storage Technologies R&D Center of Bijie High-tech Industrial Development Zone, Bijie 551712, Guizhou, China
^12.CNESA, Beijing 100190, China
^13.Zhejiang Narada Co. Ltd. , Lin'an 310030, Zhejiang, China
^14.Sungrow Co. Ltd. , Hefei 230088, Anhui, China
^15.College of Chemical and Biological Engineering, Zhejiang University, Hangzhou 310027, Zhejiang, China
^16.Shanghai Jiao Tong University, Shanghai 200240, China

Received:2022-02-26 Online:2022-03-05 Published:2022-03-11
Contact: Haisheng CHEN,Hong LI,Wentao MA,Yujie XU,Zhifeng WANG,Man CHEN,Dongxu HU,Xianfeng LI,Xisheng TANG,Yongsheng HU,Yanwei MA,Kai JIANG,Hao QIAN,Qingsong WANG E-mail:chen_hs@mail.etp.ac.cn;hli@iphy.ac.cn;xuyujie@iet.cn;Zhifeng@vip.sina.com;13926159826@139.com;@139.com;hudongxu@iet.cn;lixianfeng@dicp.ac.cn;tang@mail.iee.ac.cn;yshu@aphy.iphy.ac.cn;ywma@mail.iee.ac.cn;kjiang@hust.edu.cn;qianhhao@hyperstrong.com.cn;pinew@ustc.edu.cn

摘要/Abstract

摘要：

本文对2021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，总结得出了2021年中国储能技术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、铅蓄电池、锂离子电池、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。研究结果表明，中国储能技术在基础研究、关键技术和集成示范方面均取得了重要进展，中国已经成为世界储能技术基础研究最活跃的国家，也已成为世界储能技术研发和示范的主要核心国家之一。

关键词: 储能, 技术, 进展

Abstract:

Research and development progress on energy storage technologies of China in 2021 is reviewed in this paper. By reviewing and analyzing three aspects of research and development including fundamental study, technical research, integration and demonstration, the progress on major energy storage technologies is summarized including hydro pumped energy storage, compressed air energy storage, flywheel, lead battery, lithium-ion battery, flow battery, sodium-ion battery, supercapacitor, new technologies, integration technology, fire-control and safety technology. The results indicate that extensive improvements of China's energy storage technologies have been achieved during 2021 in terms of all the three aspects. China is now the most active country in energy storage fundamental study and also one of the core countries of technical research and demonstration.

Key words: energy storage, technology, progress

中图分类号:

TK 02

陈海生, 李泓, 马文涛, 徐玉杰, 王志峰, 陈满, 胡东旭, 李先锋, 唐西胜, 胡勇胜, 马衍伟, 蒋凯, 钱昊, 王青松, 王亮, 张新敬, 王星, 徐德厚, 周学志, 刘为, 吴贤章, 汪东林, 和庆钢, 马紫峰, 陆雅翔, 张雪松, 李泉, 索鎏敏, 郭欢, 俞振华, 梅文昕, 秦鹏. 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.

Haisheng CHEN, Hong LI, Wentao MA, Yujie XU, Zhifeng WANG, Man CHEN, Dongxu HU, Xianfeng LI, Xisheng TANG, Yongsheng HU, Yanwei MA, Kai JIANG, Hao QIAN, Qingsong WANG, Liang WANG, Xinjing ZHANG, Xing WANG, Dehou XU, Xuezhi ZHOU, Wei LIU, Xianzhang WU, Donglin WANG, Qinggang HE, Zifeng MA, Yaxiang LU, Xuesong ZHANG, Quan LI, Liumin SUO, Huan GUO, Zhenhua YU, Wenxin MEI, Peng QIN. Research progress of energy storage technology in China in 2021[J]. Energy Storage Science and Technology, 2022, 11(3): 1052-1076.

图/表 7

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图2

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表1

2021年中国储能技术与示范进展"

序号	技术类型	关键技术进展	集成示范进展
1	抽水蓄能	①大型抽水蓄能电站工程建设技术，国产盾构机抽水蓄能项目推广应用。②国内单机最大400 MW/700米水头抽水蓄能机组设计制造安装技术。③电动发电机分数极路比绕组技术在国内首次成功应用。④10 MW可变速海水抽水蓄能机组关键技术	①400 MW/700米级超高水头、高转速、大容量抽水蓄能机组。②首例高转速“零配重”抽水蓄能机组。③世界首条800米水头级的钢筋混凝土衬砌水道。④世界装机容量最大的抽水蓄能电站
2	压缩空气储能	①突破10 MW级六级间冷离心式压缩机、四级再热组合式透平膨胀级、高效超临界蓄热换热器等关键技术。②突破100 MW级宽工况组合式压缩机技术、高负荷轴流式膨胀机技术、高效蓄热换热器技术，以及系统集成与控制技术	①山东肥城国际首套10 MW盐穴先进压缩空气储能商业示范电站并网发电。②贵州毕节10 MW集气装置储气的压缩空气储能电站并网发电。③江苏金坛建设了60 MW盐穴压缩空气储能示范项目开展并网试验。④河北张家口市际首套100 MW先进压缩空气储能国家示范项目开展并网带电调试
3	储热储冷	①1100 ℃的储热陶瓷颗粒材料、700 ℃氯化物熔盐储热材料、复合相变、定形相变和仿生相变储热材料、Co₃O₄/CoO等金属氧化物反应物体系和钙基热化学储热材料等。②大容量长周期跨季节储热技术、储热储冷传热强化与材料改性技术、高效动态冰浆蓄冷技术。③系统控制与优化技术等	①采用熔盐储热的50 MW线性菲涅尔式太阳能热发电站和50 MW熔盐塔式光热发电。②张家口建成水体储热的太阳能储热采暖项目、亚临界水蓄热系统以及水合盐相变材料为冬奥会转播中心供暖。④北京实现三联供系统耦合冰蓄冷系统，基于相变材料的冷链运输技术已获得应用等
4	飞轮储能	①500 kW/180 MJ大容量飞轮本体。②300 kW级2万转高速电机技术。③飞轮储能的双馈电机励磁控制技术	①单机600 kW全磁悬浮飞轮储能系统下线。②霍林河1 MW飞轮储能系统交付。③阜新风电场站一次调频和惯量响应的飞轮储能通过并网前验收。④宁夏22 MW光火储耦合飞轮储能项目开工
5	铅蓄电池	①高电化学活性和铅炭兼容的新型炭材料。②宽温区、超长寿命、高能量转换效率、低成本的铅炭储能电池。③高电压大容量系统集成技术	①中国铁塔和中国联通分别采购1.097和1.089 GW·h铅酸铅炭电池。②2020年并网的雉城(金陵变)12 MW/48 MW·h铅炭储能项目正式运行
6	锂离子电池	①高镍正极材料。②纳米硅碳负极材料、③原位固态化锂电池技术、④混合固液电解质锂离子储能电池技术	①晋江36 MW/108 MW·h锂补偿磷酸铁锂储能系统实现示范应用。②无模组技术与刀片电池技术的推广应用。③提出锂离子和钠离子电池集成解决方案，以及三元正极与磷酸铁锂电芯混合排布的双体系电池系统等
7	液流电池	①可焊接全钒液流电池技术。②50 kW全钒液流电池大功率电堆技术。③锌基液流电池和铁铬液流电池新技术	①10 MW/40 MW·h网源友好型风场项目投运②全球首个光伏储能户外实证实验平台全钒液流电池储能系统交付③大连200 MW/800 MW·h全钒液流电池储能调峰电站一期工程完成主体工程建设
8	钠离子电池	①正负极材料制备放大技术。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。⑤电池大规模筛选及成组技术等	①全球首套1 MW·h钠离子电池光储充智能微网示范系统投入运行。②宁德时代钠离子电池产品的发布
9	超级电容器	①木质活性炭材料功能化定向调控技术。②物理沉积铝-氧化去除模板-梯度退火的泡沫铝制备技术。③负极预嵌锂技术等	①国内首套变电站超级电容微储能装置投运。②国内首个直流微网的超级电容器储能系统实现应用。③超级电容器在新能源交通领域取得了多个示范应用
10	储能新技术	①液态金属大容量电池界面稳定调控技术、表面陶瓷金属梯度化设计工艺、双等效电路融合模型、5.5 kW·h的电池组模型。②铝离子电池正极材料、锌离子负极材料等。③水系电池新型纳米结构正极材料、电解液添加剂、新型盐包水结构和水/有机共溶剂结构等	—
11	集成技术	①智能诊断技术②电池系统和PCS进行深度一体化设计技术。③高效智能温控技术和液冷技术	①高效的智能能量管理及大数据运维管理技术在海阳高能量密度1500 V磷酸铁锂储能电站得到应用。②“防护消泄”四重集成设计在乌兰察布电网友好绿色电站示范项目中应用
12	消防安全技术	①单一式热管理系统的优化和混合式热管理技术。②基于机器学习的优化预警方法和分级预警策略③间歇喷雾优化模式，新型绝缘灭火剂如全氟己酮、液氮等	多信息融合的监测预警技术和全氟己酮程控喷射技术示范应用

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2021年中国储能技术研究进展

Research progress of energy storage technology in China in 2021

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