2018年压缩空气储能技术热点回眸
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摘要
能源结构转型是世界各国正在面临的严峻问题。中国可再生能源丰富,但高比例的可再生能源渗透对电网的安全运行提出重大挑战。储能作为协同新能源运行的有效手段,可打破电能"即发即用"的特点,实现能量的高效利用。在大规模储能背景下,压缩空气储能以其自身的清洁、低成本等特点,逐步成为研究热点。2018年,压缩空气储能领域向示范工程、商业化初期不断迈进。本文回顾2018年压缩空气储能领域热点问题,总结了该领域多能互补、液化压缩、盐穴储气、循环控温、协同水利发电等技术方面的突出进展。
Transformation of energy structure is a serious problem for countries all around the world.China is rich in renewable energy but penetration of high proportion of renewable energy poses a major challenge to the safe operation of power grid.Energy storage,as an effective way to coordinate new energy sources,may breakthe characteristics of "ready-to-use" in electricity and achieveefficient utilization of energy.In terms of large-scale energy storage,compressed air energy storage has gradually become a research hotspot because of its clean and low cost characteristics.In 2018,compressed air energy storage stepped forward to demonstration project and commercialization.This paper reviews the hot topics in the field of compressed air energy storage in 2018,and summarizes and analyzes the outstanding advances in such technologies as multi-energy complementarity,liquefied compressed air,salt cavern gas storage,cyclic temperature contro land synergistic hydroelectric power generation.
Transformation of energy structure is a serious problem for countries all around the world.China is rich in renewable energy but penetration of high proportion of renewable energy poses a major challenge to the safe operation of power grid.Energy storage,as an effective way to coordinate new energy sources,may breakthe characteristics of "ready-to-use" in electricity and achieveefficient utilization of energy.In terms of large-scale energy storage,compressed air energy storage has gradually become a research hotspot because of its clean and low cost characteristics.In 2018,compressed air energy storage stepped forward to demonstration project and commercialization.This paper reviews the hot topics in the field of compressed air energy storage in 2018,and summarizes and analyzes the outstanding advances in such technologies as multi-energy complementarity,liquefied compressed air,salt cavern gas storage,cyclic temperature contro land synergistic hydroelectric power generation.
引文
[1]张华煜,陈上,朱彤,等.含有绝热压缩空气储能的分布式能源系统供能特性研究[J].中国电机工程学报,2018,38(增刊1):142-150.Zhang Huayu,Chen Shang,Zhu Tong,et al.Performance analysis of distributed energy systemwith adiabatic compressed air energy storage[J].Proceedings of the CSEE,2018,38(Suppl 1):142-150.
[2]严毅,张承慧,李珂,等.含压缩空气储能的冷热电联供微网优化运行策略[J].中国电机工程学报,2018,38(23):6924-6936,7126.Yan Yi,Zhang Chenghui,Li Ke,et al.The optimal operation strategy for hybrid combined cooling,heating and power microgrid with compressed air energy storage[J].Proceedings of the CSEE,2018,38(23):6924-6936,7126.
[3]Amirhassan S,Maryam F,Muhammadali A A,et al.Exergy analysis and optimization of a CCHP system composed of compressed air energy storage system and ORC cycle[J].Energy Conversion and Management,2018,157:111-122.
[4]Yan Y,Zhang C H,Li K,et al.An integrated design for hybrid combined cooling,heating and power system with compressed air energy storage[J].Applied Energy,2018,210:1151-1166.
[5]杨承,王旭升,张驰,等.太阳能与压缩空气耦合储能的燃气轮机CCHP系统特性[J].中国电机工程学报,2017,37(18):5350-5358,5534.Yang Cheng,Wang Xusheng,Zhang Chi,et al.Performances of gas turbine-based CCHP system combined with solar and compressed air energy storage[J].Proceedings of the CSEE,2017,37(18):5350-5358,5534.
[6]王维萌,黄葆华,宋亚军,等.10MW级深冷液化空气储能发电系统工程化应用研究进展[J].热能动力工程,2018(12):1-7.Wang Weimeng,Huang Baohua,Song Yajun,et al.Research progress on the industrial application of the 10 MW power generation system based on liquid air energy storage technology[J].Journal of Engineering for Thermal Energy and Power,2018(12):1-7.
[7]安保林,王俊杰,段远源.联合液化空气储能的有机朗肯循环研究[J].工程热物理学报,2018,39(3):471-475.An Baolin,Wang Junjie,Duan Yuanyuan.Research on the combining of organic rankine cycle and liquid air energy storage system[J].Journal of Engineering Thermophysics,2018,39(3):471-475.
[8]何青,王立健,刘文毅.深冷液化空气储能系统的热力学建模及分析[J].华中科技大学学报(自然科学版),2018,46(10):127-132.He Qing,Wang Lijian,Liu Wenyi.Thermodynamic model and exergy analysis of cryogenic liquefied air energy storage system[J].Journal of Huazhong University of Science and Technology(Natural Science Edition),2018,46(10):127-132.
[9]Krawczyk P,Szab?owski?,Karellas S,et al.Comparative thermodynamic analysis of compressed air and liquid air energy storage systems[J].Energy,2018,142:46-54.
[10]韩红静,梅生伟,王国华,等.盐穴电池储能技术及发展前景[J].全球能源互联网,2018,1(3):313-321.Han Hongjing,Mei Shengwei,Wang Guohua,et al.Salt cavern battery energy storage technology and development prospects[J].Journal of Global Energy Interconnection,2018,1(3):313-321
[11]何子伟,罗马吉,涂正凯,等.温压缩空气储能技术综述[J].热能动力工程,2018,33(2):1-6.He Ziwei,Luo Maji,Tu Zhengkai.Survey of the Isothermal compressed air energy storage technologies[J].Journal of Engineering for Thermal Energy and Power,2018,33(2):1-6.
[12]梅生伟,公茂琼,秦国良,等.基于盐穴储气的先进绝热压缩空气储能技术及应用前景[J].电网技术,2017,41(10):3392-3399.Mei Shengwei,Gong Maoqiong,Qin Guoliang,et al.An advanced adiabatic compressed air energy system based on salt cavern air storage and its application prospects[J].Power System Technology,2017,41(10):3392-3399.
[13]傅昊,张毓颖,崔岩,等.压缩空气储能技术研究进展[J].科技导报,2016,34(23):81-87.Fu Hao,Zhang Yuying,Cui Yan,et al.Research development of compressed air energy storage systems[J].Science and Technology Review,2016,34(23):81-87.
[14]Yan B,Wieberdink J,Shirazi F,et al.Experimental study of heat transfer enhancement in a liquid piston compressor/expander using porous media inserts[J].Applied Energy,2015,154:40-50.
[15]Chao Z,Perry Y L,James D,et al.Design analysis of a liquid-piston compression chamber with application to compressed air energy storage[J].Applied Thermal Engineering,2016,101:704-709.
[16]Anirudh S,Perry Y L,Farzad S How moisture content affects the performance of a liquid piston air compressor/expander[J].Journal of Energy Storage,2018,18:121-132.
[17]Chao Q,Eric L.Liquid piston compression efficiency with droplet heat transfer[J].Applied Energy,2014,114:539-550
[18]Adewale O,Edem K,Zaky H,et al.Near-isothermal-isobaric compressed gas energy storage[J].Jouranl of Energy Storage,2017,12:276-287.
[19]Zhang X,Xu Y,Zhou X,et al.A near-isothermal expander for isothermal compressed air energy storage system[J].Applied Energy,2018,225:955-964.
[20]Jia G W,Xu W Q,Mao L,et al.Micron-sized water spraycooled quasi-isothermal compression for compressed air energy storage[J].Experimental Thermal&Fluid Science,2018,96:470-481.
[21]Fu H,Jiang T,Cui Y,et al.Adaptive hydraulic potential energy transfer technology and its application to compressed air energy storage[J].Energies,2018,11(7):1-13.
[22]Erren Y,Huanran W,Long L,et al.A novel constant-pressure pumped hydro combined with compressed air energy storage system[J].Energies,2015,8(1):154-171.
[23]Chun T C,Cheng G S,Pei L W,et al.An MILP-based model for short-term peak shaving operation of pumped-storage hydropower plants serving multiple power grids[J].Energy,2018,163:722-733.
[24]Bahadur S P,Shelly V.A novel pumped hydro-energy storage scheme with wind energy for power generation at constant voltage in rural areas[J].Renewable Energy,2018,127:802-810.
[2]严毅,张承慧,李珂,等.含压缩空气储能的冷热电联供微网优化运行策略[J].中国电机工程学报,2018,38(23):6924-6936,7126.Yan Yi,Zhang Chenghui,Li Ke,et al.The optimal operation strategy for hybrid combined cooling,heating and power microgrid with compressed air energy storage[J].Proceedings of the CSEE,2018,38(23):6924-6936,7126.
[3]Amirhassan S,Maryam F,Muhammadali A A,et al.Exergy analysis and optimization of a CCHP system composed of compressed air energy storage system and ORC cycle[J].Energy Conversion and Management,2018,157:111-122.
[4]Yan Y,Zhang C H,Li K,et al.An integrated design for hybrid combined cooling,heating and power system with compressed air energy storage[J].Applied Energy,2018,210:1151-1166.
[5]杨承,王旭升,张驰,等.太阳能与压缩空气耦合储能的燃气轮机CCHP系统特性[J].中国电机工程学报,2017,37(18):5350-5358,5534.Yang Cheng,Wang Xusheng,Zhang Chi,et al.Performances of gas turbine-based CCHP system combined with solar and compressed air energy storage[J].Proceedings of the CSEE,2017,37(18):5350-5358,5534.
[6]王维萌,黄葆华,宋亚军,等.10MW级深冷液化空气储能发电系统工程化应用研究进展[J].热能动力工程,2018(12):1-7.Wang Weimeng,Huang Baohua,Song Yajun,et al.Research progress on the industrial application of the 10 MW power generation system based on liquid air energy storage technology[J].Journal of Engineering for Thermal Energy and Power,2018(12):1-7.
[7]安保林,王俊杰,段远源.联合液化空气储能的有机朗肯循环研究[J].工程热物理学报,2018,39(3):471-475.An Baolin,Wang Junjie,Duan Yuanyuan.Research on the combining of organic rankine cycle and liquid air energy storage system[J].Journal of Engineering Thermophysics,2018,39(3):471-475.
[8]何青,王立健,刘文毅.深冷液化空气储能系统的热力学建模及分析[J].华中科技大学学报(自然科学版),2018,46(10):127-132.He Qing,Wang Lijian,Liu Wenyi.Thermodynamic model and exergy analysis of cryogenic liquefied air energy storage system[J].Journal of Huazhong University of Science and Technology(Natural Science Edition),2018,46(10):127-132.
[9]Krawczyk P,Szab?owski?,Karellas S,et al.Comparative thermodynamic analysis of compressed air and liquid air energy storage systems[J].Energy,2018,142:46-54.
[10]韩红静,梅生伟,王国华,等.盐穴电池储能技术及发展前景[J].全球能源互联网,2018,1(3):313-321.Han Hongjing,Mei Shengwei,Wang Guohua,et al.Salt cavern battery energy storage technology and development prospects[J].Journal of Global Energy Interconnection,2018,1(3):313-321
[11]何子伟,罗马吉,涂正凯,等.温压缩空气储能技术综述[J].热能动力工程,2018,33(2):1-6.He Ziwei,Luo Maji,Tu Zhengkai.Survey of the Isothermal compressed air energy storage technologies[J].Journal of Engineering for Thermal Energy and Power,2018,33(2):1-6.
[12]梅生伟,公茂琼,秦国良,等.基于盐穴储气的先进绝热压缩空气储能技术及应用前景[J].电网技术,2017,41(10):3392-3399.Mei Shengwei,Gong Maoqiong,Qin Guoliang,et al.An advanced adiabatic compressed air energy system based on salt cavern air storage and its application prospects[J].Power System Technology,2017,41(10):3392-3399.
[13]傅昊,张毓颖,崔岩,等.压缩空气储能技术研究进展[J].科技导报,2016,34(23):81-87.Fu Hao,Zhang Yuying,Cui Yan,et al.Research development of compressed air energy storage systems[J].Science and Technology Review,2016,34(23):81-87.
[14]Yan B,Wieberdink J,Shirazi F,et al.Experimental study of heat transfer enhancement in a liquid piston compressor/expander using porous media inserts[J].Applied Energy,2015,154:40-50.
[15]Chao Z,Perry Y L,James D,et al.Design analysis of a liquid-piston compression chamber with application to compressed air energy storage[J].Applied Thermal Engineering,2016,101:704-709.
[16]Anirudh S,Perry Y L,Farzad S How moisture content affects the performance of a liquid piston air compressor/expander[J].Journal of Energy Storage,2018,18:121-132.
[17]Chao Q,Eric L.Liquid piston compression efficiency with droplet heat transfer[J].Applied Energy,2014,114:539-550
[18]Adewale O,Edem K,Zaky H,et al.Near-isothermal-isobaric compressed gas energy storage[J].Jouranl of Energy Storage,2017,12:276-287.
[19]Zhang X,Xu Y,Zhou X,et al.A near-isothermal expander for isothermal compressed air energy storage system[J].Applied Energy,2018,225:955-964.
[20]Jia G W,Xu W Q,Mao L,et al.Micron-sized water spraycooled quasi-isothermal compression for compressed air energy storage[J].Experimental Thermal&Fluid Science,2018,96:470-481.
[21]Fu H,Jiang T,Cui Y,et al.Adaptive hydraulic potential energy transfer technology and its application to compressed air energy storage[J].Energies,2018,11(7):1-13.
[22]Erren Y,Huanran W,Long L,et al.A novel constant-pressure pumped hydro combined with compressed air energy storage system[J].Energies,2015,8(1):154-171.
[23]Chun T C,Cheng G S,Pei L W,et al.An MILP-based model for short-term peak shaving operation of pumped-storage hydropower plants serving multiple power grids[J].Energy,2018,163:722-733.
[24]Bahadur S P,Shelly V.A novel pumped hydro-energy storage scheme with wind energy for power generation at constant voltage in rural areas[J].Renewable Energy,2018,127:802-810.