“光储直柔”建筑新型能源系统发展现状与研究展望
引用文献:
刘晓华 张涛 刘效辰 江亿. “光储直柔”建筑新型能源系统发展现状与研究展望[J]. 暖通空调,2022,48(8)国家电网公司科技项目(编号:5400-202219175A-1-1-ZN);华能集团总部科技项目基础能源科技研究专项(编号:HNKJ20-H50);.
Liu Xiaohua Zhang Tao Liu Xiaochen Jiang Yi. Development statuses and research prospects of PEDF (photovoltaics, energy storage, direct current and flexibility) building energy systems[J]. build,2022,48(8)国家电网公司科技项目(编号:5400-202219175A-1-1-ZN);华能集团总部科技项目基础能源科技研究专项(编号:HNKJ20-H50);.
摘要:“光储直柔”建筑新型能源系统是面向碳中和目标实现建筑能源系统革新的重要技术路径。本文对其关键环节的构建提出了基本认识:在建筑光伏利用中应当充分利用建筑自身表面资源,并根据建筑类型区分;需要重新认识建筑中各类可视为储能的资源,挖掘建筑侧的储能潜力;根据需求设置直流配电系统并实现有效的系统柔性调节。对现有“光储直柔”建筑案例进行了简要介绍,并对未来需开展的研究进行了展望,以期为“光储直柔”的进一步深入研究、探索提供参考。
关键词:光储直柔系统构建建筑等效储能建筑柔性研究展望
基金:国家电网公司科技项目(编号:5400-202219175A-1-1-ZN);华能集团总部科技项目基础能源科技研究专项(编号:HNKJ20-H50);
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[2] 清华大学建筑节能研究中心.中国建筑节能年度发展研究报告2022[M].北京:中国建筑工业出版社,2022:77- 82.
[3] 中华人民共和国国务院.关于印发2030年前碳达峰行动方案的通知(国发[2021]23号)[EB/OL].(2021-10-24)[2022-03-25].http://www.gov.cn/zhengce/content/2021-10/26/content_5644984.htm.
[4] 住房和城乡建设部.关于印发“十四五”建筑节能与绿色建筑发展规划的通知[EB/OL].(2022-03-01)[2022-03-25].https://www.mohurd.gov.cn/gongkai/ fdzdgknr/ zfhcxjsbwj/ 202203/ 20220311_765109.html.
[5] 国家发展改革委,国家能源局.关于完善能源绿色低碳转型体制机制和政策措施的意见[EB/OL].(2022-01-30)[2022-03-25].https://www.ndrc.gov.cn/xxgk/zcfb/tz/202202/t20220210_1314511.html?code=&state=123.
[6] 国家发展改革委,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)[2022-03-25].http://zfxxgk.nea.gov.cn/2022-01/29/c_1310523208.htm.
[7] 工业和信息化部,住房和城乡建设部,交通运输部,等.关于印发《智能光伏产业创新发展行动计划(2021—2025年)》的通知[EB/OL].(2021-12-31)[2022-03-25].http://www.gov.cn/zhengce/zhengceku/2022-01/05/content_5666484.htm.
[8] 王光辉,唐新明,张涛,等.全国建筑物遥感监测与分布式光伏建设潜力分析[J].中国工程科学,2021,23(6):92- 100.
[9] 姚春妮,马欣伯,罗多.碳达峰目标下太阳能光电建筑应用发展规模预测研究[J].建设科技,2021(11):33- 35.
[10] 陈文波,郝斌.碳中和背景下农村光储直柔系统建设分析:以山西省芮城县东夭村为例[J].建设科技,2021(7):86- 89.
[11] CHEN Q,KUANG Z,LIU X,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.
[12] PENG X,HAVES P,PIETTE M A,et al.Peak demand reduction from pre-cooling with zone temperature reset in an office building[R].California:Lawrence Berkeley National Laboratory,2004:1- 11.
[13] ADUDA K,LABEODAN T,ZEILER W,et al.Demand side flexibility:potentials and building performance implications[J].Sustainable cities and society,2016,22(4):146- 163.
[14] ALI M,JOKISALO J,SIREN K,et al.Combining the demand response of direct electric space heating and partial thermal storage using LP optimization[J].Electric power systems research,2014,106(1):160- 167.
[15] 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.
[16] 付智.建筑光伏直连式电动汽车智能充电系统性能研究[D].北京:清华大学,2022:20- 32.
[17] 欧阳明高.推动电动汽车车网互动(V2G)储能技术发展[EB/OL].(2022-03-08)[2022-03-26].https://www.tsinghua.edu.cn/info/2815/91992.htm.
[18] 李雨桐,郝斌,童亦斌,等.民用建筑低压直流配用电系统关键技术认识与思考[J].建设科技,2020(6):32- 36.
[19] 深圳市建筑科学研究院有限公司.民用建筑直流配电设计标准:T/CABEE 030—2022[S].北京:中国建筑工业出版社,2022:1- 7.
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[21] ELTAWIL M A,ZHAO Z.MPPT techniques for photovoltaic applications[J].Renewable and sustainable energy reviews,2013,25:793- 813.
[22] JIN C,WANG P,XIAO J,et al.Implementation of hierarchical control in DC microgrids[J].IEEE transactions on industrial electronics,2014,61(8):4032- 4042.
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[25] 郝斌.建筑“光储直柔”与零碳电力如影随形[J].建筑,2021(23):27- 29.
[26] 李叶茂,李雨桐,郝斌,等.低碳发展背景下的建筑“光储直柔”配用电系统关键技术分析[J].供用电,2021,38(1):32- 38.
Development statuses and research prospects of PEDF (photovoltaics, energy storage, direct current and flexibility) building energy systems
Abstract: PEDF(photovoltaics, energy storage, direct current and flexibility) is a kind of novel building energy system towards carbon neutrality. It is an important technical path to realize building energy system innovation under the goal of carbon neutrality. In this paper, the basic understanding of the construction of the key links is put forward, where it should make full use of its own surface resources in the utilization of building photovoltaic, and distinguish according to the building type. It is necessary to re-understand all kinds of resources that can be regarded as energy storage in buildings and tap the potential of energy storage in buildings, and to set up DC power distribution system according to requirements and realize effective system flexibility adjustment. The existing cases of PEDF buildings are briefly introduced, and the future research is prospected, in order to provide references for further research and exploration of the PEDF buildings.
Keywords: PEDF(photovoltaics,energy storage,direct current and flexibility); system construction; building equivalent energy storage; building flexibility; research prospect;
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