“双碳”目标下车建筑电网VBG)协同互动的探索
引用文献:
张涛 刘晓华 刘效辰. “双碳”目标下车建筑电网VBG)协同互动的探索[J]. 暖通空调,2023,48(5)国家重点研发计划项目(编号:2022YFC3802500);国家电网公司科技项目(编号:5400-202219175A-1-1-ZN);.
Zhang Tao Liu Xiaohua Liu Xiaochen. Exploration of vehicle-building-grid (VBG) collaborative interaction under dual carbon target[J]. build,2023,48(5)国家重点研发计划项目(编号:2022YFC3802500);国家电网公司科技项目(编号:5400-202219175A-1-1-ZN);.
摘要:建筑是重要的电力终端用户,碳中和目标下将实现电力生产、消费、调蓄“三位一体”功能;汽车(特别是私家车)电动化是交通领域碳中和的重要举措,也有望成为未来电力系统中可利用的重要调蓄资源。建筑与电动车是重要的电力终端用户且有高度同步使用特征,二者协同起来可实现优势互补,由此能与电网实现良好互动。如何实现车-建筑-电网(VBG)之间的友好互动,如何充分发挥建筑、车作为电力系统灵活负载的资源潜力,如何有效调节、调度建筑、车与电力系统实现能量交互,是当前亟需回答的重要问题。本文对上述问题的相关研究进展进行了分析,并对未来需开展的研究进行了展望,以期为进一步深入研究、探索车-建筑-电网之间的协同互动提供参考。
关键词:建筑能源系统电动汽车等效储能车-建筑-电网VBG)互动灵活性
基金:国家重点研发计划项目(编号:2022YFC3802500);国家电网公司科技项目(编号:5400-202219175A-1-1-ZN);
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参考文献[1] 周孝信,赵强,张玉琼.“双碳”目标下我国能源电力系统发展前景和关键技术[J].中国电力企业管理,2021,31(11):14- 17.
[2] 刘晓华.碳中和目标下建筑能源系统再认识[J].可持续发展经济导刊,2022(4):36- 37.
[3] 彭天铎,袁志逸,任磊,等.中国碳中和目标下交通部门低碳发展路径研究[J].汽车工程学报,2022,12(4):351- 359.
[4] 王贺武,欧阳明高,李建秋,等.中国氢燃料电池汽车技术路线选择与实践进展[J].汽车安全与节能学报,2022,13(2):211- 224.
[5] WANG Y,INFIELD D.Markov Chain Monte Carlo simulation of electric vehicle use for network integration studies[J].International journal of electrical power & energy systems,2018,99:85- 94.
[6] CHEN Q,KUANG Z H,LIU X H,et al.Energy storage to solve the diurnal,weekly,and seasonal mismatch and achieve zero-carbon electricity consumption in buildings[J].Applied energy,2022,312:118744.
[7] 魏一凡,韩雪冰,卢兰光,等.面向碳中和的新能源汽车与车网互动技术展望[J].汽车工程,2022,44(4):449- 464.
[8] ZHANG X D,ZOU Y,FAN J,et al.Usage pattern analysis of Beijing private electric vehicles based on real-world data[J].Energy,2019,167:1074- 1085.
[9] 国家能源局,科技部.关于印发《“十四五”能源领域科技创新规划》的通知[EB/OL].[2022-10-21].http://www.gov.cn/zhengce/zhengceku/2022-04/03/content_5683361.htm.
[10] WEI H Q,ZHANG Y T,WANG Y Z,et al.Planning integrated energy systems coupling V2G as a flexible storage[J].Energy,2022,239:122215.
[11] BENJAMIN K S,JOHANNES K,LANCE N,et al.Actors,business models,and innovation activity systems for vehicle-to-grid (V2G) technology:a comprehensive review[J].Renewable and sustainable energy reviews,2020,131:109963.
[12] MUSTAFA I,MURAT M S,ÖZGÜR C.Integrating electric vehicles as virtual power plants:a comprehensive review on vehicle-to-grid (V2G) concepts,interface topologies,marketing and future prospects[J].Journal of energy storage,2022,55:105579.
[13] POWELL S,CEZAR G V,MIN L,et al.Charging infrastructure access and operation to reduce the grid impacts of deep electric vehicle adoption[J].Nature energy,2022,7:932- 945.
[14] 欧阳明高.面向碳中和的新能源汽车创新与发展[J].科学中国人,2021(4):26- 31.
[15] 国网江西电力首次邀约百万居民开展需求响应试点工作[EB/OL].[2022-10-21].https://baijiahao.baidu.com/s?id=1686222670000309512&wfr=spider&for=pc.
[16] JENSEN S ∅,MARSZAL-POMIANOWSKA A,LOLLINI R,et al.IEA EBC Annex 67 energy flexible buildings[J].Energy and buildings,2017,155:25- 34.
[17] 林琳.航站楼多区域客流与供冷需求特征研究[D].北京:清华大学,2022:97- 111.
[18] LI W Q,GONG G C,REN Z J,et al.A method for energy consumption optimization of air conditioning systems based on load prediction and energy flexibility[J].Energy,2022,243:123111.
[19] 江亿.“光储直柔”——助力实现零碳电力的新型建筑配电系统[J].暖通空调,2021,51(10):1- 12.
[20] 刘晓华,张涛,刘效辰.如何描述建筑在新型电力系统中的基本特征?——现状与展望[J].暖通空调,2023,53(1):1- 10,124.
[2] 刘晓华.碳中和目标下建筑能源系统再认识[J].可持续发展经济导刊,2022(4):36- 37.
[3] 彭天铎,袁志逸,任磊,等.中国碳中和目标下交通部门低碳发展路径研究[J].汽车工程学报,2022,12(4):351- 359.
[4] 王贺武,欧阳明高,李建秋,等.中国氢燃料电池汽车技术路线选择与实践进展[J].汽车安全与节能学报,2022,13(2):211- 224.
[5] WANG Y,INFIELD D.Markov Chain Monte Carlo simulation of electric vehicle use for network integration studies[J].International journal of electrical power & energy systems,2018,99:85- 94.
[6] CHEN Q,KUANG Z H,LIU X H,et al.Energy storage to solve the diurnal,weekly,and seasonal mismatch and achieve zero-carbon electricity consumption in buildings[J].Applied energy,2022,312:118744.
[7] 魏一凡,韩雪冰,卢兰光,等.面向碳中和的新能源汽车与车网互动技术展望[J].汽车工程,2022,44(4):449- 464.
[8] ZHANG X D,ZOU Y,FAN J,et al.Usage pattern analysis of Beijing private electric vehicles based on real-world data[J].Energy,2019,167:1074- 1085.
[9] 国家能源局,科技部.关于印发《“十四五”能源领域科技创新规划》的通知[EB/OL].[2022-10-21].http://www.gov.cn/zhengce/zhengceku/2022-04/03/content_5683361.htm.
[10] WEI H Q,ZHANG Y T,WANG Y Z,et al.Planning integrated energy systems coupling V2G as a flexible storage[J].Energy,2022,239:122215.
[11] BENJAMIN K S,JOHANNES K,LANCE N,et al.Actors,business models,and innovation activity systems for vehicle-to-grid (V2G) technology:a comprehensive review[J].Renewable and sustainable energy reviews,2020,131:109963.
[12] MUSTAFA I,MURAT M S,ÖZGÜR C.Integrating electric vehicles as virtual power plants:a comprehensive review on vehicle-to-grid (V2G) concepts,interface topologies,marketing and future prospects[J].Journal of energy storage,2022,55:105579.
[13] POWELL S,CEZAR G V,MIN L,et al.Charging infrastructure access and operation to reduce the grid impacts of deep electric vehicle adoption[J].Nature energy,2022,7:932- 945.
[14] 欧阳明高.面向碳中和的新能源汽车创新与发展[J].科学中国人,2021(4):26- 31.
[15] 国网江西电力首次邀约百万居民开展需求响应试点工作[EB/OL].[2022-10-21].https://baijiahao.baidu.com/s?id=1686222670000309512&wfr=spider&for=pc.
[16] JENSEN S ∅,MARSZAL-POMIANOWSKA A,LOLLINI R,et al.IEA EBC Annex 67 energy flexible buildings[J].Energy and buildings,2017,155:25- 34.
[17] 林琳.航站楼多区域客流与供冷需求特征研究[D].北京:清华大学,2022:97- 111.
[18] LI W Q,GONG G C,REN Z J,et al.A method for energy consumption optimization of air conditioning systems based on load prediction and energy flexibility[J].Energy,2022,243:123111.
[19] 江亿.“光储直柔”——助力实现零碳电力的新型建筑配电系统[J].暖通空调,2021,51(10):1- 12.
[20] 刘晓华,张涛,刘效辰.如何描述建筑在新型电力系统中的基本特征?——现状与展望[J].暖通空调,2023,53(1):1- 10,124.
Exploration of vehicle-building-grid (VBG) collaborative interaction under dual carbon target
Abstract: Buildings are important end-users of electricity. Under the goal of carbon neutrality, the “trinity” of electricity production, consumption, regulation and storage will be realized. The electrification of vehicles(especially private cars) is an important measure for carbon neutrality in the transportation sector, and it is also expected to become an important regulation and storage resource available in the future power system. Buildings and electric vehicles are important end-users of electric power and have highly synchronous usage characteristics. When they work together, they can realize complementary advantages and achieve good interaction with the electric power system. How to realize the friendly interaction between vehicles, buildings and grids, how to give full play to the resources potential of buildings and vehicles as flexible loads of power systems, and how to effectively regulate and dispatch buildings, vehicles and power systems to achieve energy interaction are important questions that need to be answered. In this paper, the research progress of the above issues is analysed, and the future research that needs to be carried out is prospected, in order to provide a reference for further research and exploration of collaborative interaction between vehicles, buildings and grids.
Keywords: building energy system; electric vehicle; equivalent energy storage; vehicle-building-grid(VBG) collaborative interaction; flexibility;
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