交直流混合微电网接入分布式新能源的关键技术研究综述

doi:10.3969/j.issn.1000－7229.2017.03.002

摘要/Abstract

摘要： 随着传统能源的日益短缺和环境问题的日趋严重，分布式电源接入是电网发展的必然趋势。微电网是促进分布式能源消纳与管理的有效模式，而交直流混合微电网因其兼备交流微电网与直流微电网的优点，已成为研究热点。该文综合国内外交直流混合微电网的已有研究成果和相关内容，从交直流混合微电网的拓扑结构与容量配置、性能评估、电源管理与保护技术等方面进行总结概括，并对交直流混合微电网的发展前景和实际应用的相关问题做出展望，对国内交直流混合微电网的进一步发展提供相关思路，具备现实意义。

关键词: , 交直流混合微电网, 拓扑结构, 容量配置, 性能评估, 电源管理, 保护技术

Abstract: With the problems of energy shortage and environmental crisis, the integration of distributed energy is the essential way to develop power grid. Microgrid is an effective mode to promote the consumption and management of distributed energy, and AC/DC hybrid microgrid becomes a hot topic due to the advantages of both AC microgrid and DC microgrid. According to the existing research achievements about AC/DC hybrid microgrid domestic and overseas, this paper summarizes the topological structure and capacity allocation, performance evaluation, power management and protection technology of AC/DC hybrid microgrid. Then, this paper discusses the development prospect and practical application of AC/DC hybrid microgrid, and proposes some suggestions for the further development of AC/DC hybrid microgrid in China, which has practical significance.

Key words: AC/DC hybrid microgrid, topological structure, capacity allocation, performance evaluation, power management, protection technology

中图分类号:

TM 727

郭雅娟，陈锦铭，何红玉，吴倩红，韩蓓，李国杰. 交直流混合微电网接入分布式新能源的关键技术研究综述[J]. 电力建设, 2017, 38(3): 9-.

GUO Yajuan，CHEN Jinming，HE Hongyu， WU Qianhong，HAN Bei，LI Guojie2. A Review on AC/DC Hybrid Microgrid Key Technology Containing Distributed New Energy[J]. Electric Power Construction, 2017, 38(3): 9-.

参考文献

［1］中华人民共和国国务院.国家中长期科学和技术发展规划纲要（2006-2020年）［EB/OL］. （2006-02-09）［2016-11-02］. http://www.gov.cn/jrzg/2006-02/09/content_183787.htm.

［2］中华人民共和国国务院.能源发展战略行动计划（2014—2020年）［EB/OL］. (2014-11-19)［2016-11-02］. http://www.gov.cn/zhengce/content/2014-11/19/content_9222.htm.

［3］国家能源局.配电网建设改造行动计划（2015-2020年）［EB/OL］. (2015-07-31)［2016-11-02］. http://zfxxgk.nea.gov.cn/auto84/201508/t20150831_1958.htm?keywords=.

［4］中华人民共和国国务院.中国制造2025［EB/OL］. （2015-05-08）［2016-11-02］. http://www.gov.cn/zhengce/content/2015-05/19/content_9784.htm.

［5］中华人民共和国国务院.关于积极推进“互联网+”行动的指导意见［EB/OL］. (2015-07-04)［2016-11-02］.http://www.gov.cn/zhengce/content/2015-07/04/content_10002.htm.

［6］丁明, 田龙刚, 潘浩,等. 交直流混合微电网运行控制策略研究［J］. 电力系统保护与控制, 2015，43(9):1-8.

DING Ming, TIAN Longgang, PAN Hao, et al. Research on control strategy of hybrid AC/DC microgrid［J］. Power System Protection and Control,2015，43(9):1-8.

［7］MARNAY C, ROBIO F J, SIDDIQUI A S. Shape of the microgrid［C］// Power Engineering Society Winter Meeting. Columbus: IEEE, 2001: 150-153.

［8］LASSETTER R, AKHIL A, MARNAY C. Integration of distributed energy resources: the CERTS microgrid concept［R］. Berkeley, CA (US): Ernest Orlando Lawrence Berkeley National Laboratory, 2002.

［9］SALOMONSSON D, SANNINO A. Low-voltage DC distribution system for commercial power systems with sensitive electronic loads ［J］. IEEE Transactions on Power Delivery, 2007, 22(3) : 1620-1627.

［10］TSUJI K. FRIENDS in the context of microgrid research［EB/OL］.(2005-06-17)［2016-11-02］. http://der.lbl.gov/new_site/DER.htm.

［11］MOROZUMI S. Overview of micro-grid research and development activities in Japan［EB/OL］.(2006-07-23)［2016-11-02］. http://www.microgrids.eu/documents/165.pdf

［12］MENG N, WANG P, WU H, et al. Optimal sizing of distributed generations in a connected DC micro-grid with hybrid energy storage system［C］// 2015 IEEE Energy Conversion Congress and Exposition (ECCE). Montréal, CA: IEEE, 2015: 3179-3183.

［13］马溪原，吴耀文，方华亮，等. 釆用改进细菌觅食算法的风光储混合微电网电源优化配置［J］.中国电机工程学报，2011，31(25)：17-25.

MA Xiyuan, WU Yaowen, FANG Hualiang, et al. Optimal sizing of hybrid solar-wind distributed generation in an islanded microgrid using improved bacterial foraging algorithm［J］. Proceedings of the CSEE, 2011, 31(25): 17-25.

［14］丁明, 王波, 赵波，等. 独立风光柴储微网系统容量优化配置［J］. 电网技术, 2013, 37(3): 575-581.

DING Ming, WANG Bo, ZHAO Bo, et al. Configuration optimization of capacity of standalone PV-wind-diesel-battery hybrid microgrid［J］. Power System Technology, 2013, 37(3):575-581.

［15］BILAL B O, SAMBOU V,P. NDIAYE A, et al. Optimal design of a hybrid solar-wind-battery system using the minimization of the annualized cost system and the minimization of the loss of power supply probability(LPSP) ［J］. Renewable Energy, 2010,35(10): 2388-2390.

［16］KAABECHE A, BELHAMEL M, IBTIOUEN R. Sizing optimization of grid-independent hybrid photovoltaic/wind power generation system［J］. Energy, 2011, 36(2): 1214-1222.

［17］何俊, 邓长虹, 徐秋实，等. 基于等可信容量的风光储电源优化配置方法［J］. 电网技术, 2013, 37(12): 3317-3324

HE Jun, DENG Changhong, XU Qiushi, et al. Optimal configuration of distributed generation system containing wind PV battery power sources based on equivalent credible capacity theory［J］. Power System Technology, 2013, 37(12):3317-3324.

［18］王阳，鲁宗相，闵勇，等. 基于降阶模型的多电源微电网小干扰分析［J］.电工技术学报，2011，27（1）：1-8.

WANG Yang, LU Zongxiang, MIN Yong, et al.Small-signal analysis of micro-grid with multiple micro sources based on reduced order model in islanding operation［J］. Transactions of China Electrotechnical Society, 2011，27(1)：1-8.

［19］郑竞宏，李兴旺，王燕廷，等.微电网切换至孤岛运行时的小信号稳定性分析［J］.电力系统自动化，2012，36（15）：25-32.

ZHENG Jinghong, LI Xingwang, WANG Yanting, et al. Small-signal stability analysis of a microgrid switching to islanded mode［J］. Automation of Electric Power Systems, 2012, 36(15):25-32.

［20］RESE L，COSTA A S，ASE S. Small-signal modeling and analysis of microgrids including network and VSI dynamics［J］. Power and Energy Society General Meeting, 2012 IEEE.San Diego, California USA: IEEE, 2012:1-8.

［21］赵冬梅，张佳军，刘海涛，等. 风光储气微电网暂态稳定性仿真［J］. 华东电力，2012，40（8）：1379-1383.

ZHAO Dongmei, ZHANG Jiajun, LIU Haitao, et al. Transient stability simulation of wind/PV/battery/gas hybrid microgrid［J］. East China Electric Power, 2012,40（8）：1379-1383.

［22］肖朝霞，方红伟. 含多分布式电源的微网暂态稳定分析［J］.电工技术学报，2011，26（1）：253-260.

XIAO Zhaoxia, FANG Hongwei. Transient stability analysis of microgrids containing multiple micro sources［J］. Transactions of China Electrotechnical Society, 2011,26（1）：253-260.

［23］KASEM ALABOUDY A H, ZEINELDIN H H, KIRTLEY J L. Microgrid stability characterization subsequent to fault-triggered islanding incidents［J］. IEEE Transactions on Power Delivery, 2012, 27(2):658-669..

［24］IBRAHIM H M, EL MOURSI M S, HUANG P H. Adaptive roles of islanded microgrid components for voltage and frequency transient responses enhancement［J］. IEEE Transactions on Industrial Informatics, 2015, 11(6):1298-1312.

［25］赵勇帅，赵渊，卢晶晶，等. 光伏发电系统可靠性建模及对配电网可靠性的影响［J］. 华东电力，2013，41(9)：1783-1789.

ZHAO Yongshuai， ZHAO Yuan， LU Jingjing, et al. Reliability model of PV generation system and its effect on distribution network reliability［J］. East China Electric Power, 2013, 41(9)：1783-1789.

［26］王震，鲁宗相，段晓波，等. 分布式光伏发电系统的可靠性模型及指标体系［J］. 电力系统自动化，2011，35(15)：18-24.

WANG Zhen, LU Zongxiang, DUAN Xiaobo, et al. Reliability model and indices of distributed photovoltaic power system［J］. Automation of Electric Power Systems, 2011, 35(15):18-24.

［27］吴义纯，丁明. 基于蒙特卡罗仿真的风力发电系统可靠性评价［J］. 电力自动化设备，2004，24(12)：70-73.

WU YiChun, DING Ming. Reliability assessment of wind power generation system based on Monte-Carlo simulation［J］. Electric Power Automation Equipment, 2004，24(12)：70-73.

［28］CONTI S, RIZZO S A. Modelling of microgrid-renewable generators accounting for power-output correlation［J］. IEEE Transactions on Power Delivery, 2013, 28(4): 2124-2133.

［29］GHAHDERIJANI M M, BARAKATI S M, JAMSHIDI A. Application of stochastic simulation method in reliability assessment of a PV-wind-diesel-SOFC hybrid microgrid［J］. International Journal of Engineering and Technology, 2012, 4(5): 586-589.

［30］BAE I S, KIM J O. Reliability evaluation of customers in a microgrid［J］. IEEE Transactions on Power Systems, 2008, 23(3): 1416-1422.

［31］王旭东，林济铿. 基于网络化简的含分布式电源的配电网可靠性分析［J］. 电力系统自动化，2010，34(4)：38-43.

WANG Xudong, LIN Jikeng. Reliability evaluation based on network simplification for the distribution system with distributed generation［J］. Automation of Electric Power Systems, 2010, 34(4):38-43.

［32］葛少云，王浩鸣. 基于系统状态转移抽样的含分布式电源配电网可靠性评估［J］. 电力系统自动化，2013，37(2)：28-35.

GE Shaoyun, WANG Haoming. Reliability evaluation of distribution networks including distributed generations based on system state transition sampling［J］. Automation of Electric Power Systems, 2013, 37(2):28-35.

［33］卢晶晶，赵渊，赵永帅，等. 含分布式电源配电网可靠性评估的点估计法［J］. 电网技术，2013，37(8)：2250-2257.

LU Jingjing, Zhao Yuan, Zhao Yongshuai, et al. A point estimation method for reliability evaluation of distribution network with distributed generation［J］. Power System Technology, 2013,37(10):2250-2257.

［34］DA SILVA A M L, NASCIMENTO L C, DA ROSA M A, et al. Distributed energy resources impact on distribution system reliability under load transfer restrictions［J］. IEEE Transactions on Smart Grid, 2012, 3(4): 2048-2055.

［35］解翔，袁越，李振杰. 含微电网的新型配电网供电可靠性分析［J］. 电力系统自动化，2011，35(9)：67-72.

XIE Xiang, YUAN Yue, LI Zhenjie. Reliability analysis of a novel distribution network with microgrid［J］. Automation of Electric Power Systems, 2011，35(9)：67-72.

［36］杨琦，马世英，唐晓骏，等. 微电网规划评价指标体系构建与应用［J］. 电力系统自动化，2012，36(9)：13-17.

YANG Qi, MA Shiying, TANG Xiaojun, et al. Evaluation index system construction and application of microgrid planning［J］. Automation of Electric Power Systems, 2012，36(9)：13-17.

［37］罗奕，王钢，汪隆君. 微网可靠性评估指标研究［J］. 电力系统自动化，2013，37(5)：9-14.

LUO Yi, WANG Gang, WANG Longjun. Reliability evaluation indices for microgrid［J］. Automation of Electric Power Systems, 2013, 37(5):9-14.

［38］曾鸣, 李娜, 马明娟, 等. 考虑不确定因素影响的独立微网综合性能评价模型［J］. 电网技术, 2013, 37(1): 1-8.

ZENG Ming, LI Na, MA Mingjuan, et al. An integrated performance evaluation model of independent microgrid considering impacts of uncertain factors［J］. Power System Technology, 2013, 37(1):1-8.

［39］喻志成. 独立微网安全性评价模型与方法研究［D］. 长沙：湖南大学, 2014.

YU Zhicheng. Research on the model and approach of stand-alone microgrid security evaluation［D］. Changsha: Hunan University, 2014.

［40］周二雄, 李凤婷, 朱贺. 基于生命周期微网的经济性分析［J］. 可再生能源, 2013, 31(7):37-40.

ZHOU Erxiong, LI Fengting, ZHU He. Economic analysis for microgrid based on life cycle［J］. Renewable Energy Resources, 2013, 31(7):37-40.

［41］刘忠义, 李庚银. 混合型孤立微网全寿命周期经济性评估［J］. 现代电力, 2015, 32(4):1-7.

LIU Zhongyi, LI Gengyin. Full life-cycle economic evaluation of hybrid isolated microgrid［J］. Modern Electric Power, 2015, 32(4):1-7.

［42］RAMABHOTLA S, BAYNE S, GIESSELMANN M. Economic dispatch optimization of microgrid in islanded mode［C］// Energy and Sustainability Conference. Lubbock, TX: IEEE, 2014:1279-1296.

［43］陈洁, 杨秀, 朱兰,等. 微网多目标经济调度优化［J］. 中国电机工程学报, 2013,33(19):57-66.

CHEN Jie, YANG Xiu, ZHU Lan, et al. Microgrid multi-objective economic dispatch optimization［J］. Proceedings of the CSEE, 2013, 33(19):57-66.

［44］吴雄, 王秀丽, 王建学,等. 微网经济调度问题的混合整数规划方法［J］.中国电机工程学报, 2013,33(28):1-8.

WU Xiong, WANG Xiuli, WANG Jianxue, et al. Economic generation scheduling of a microgrid using mixed integer linear programming［J］. Proceedings of the CSEE, 2013, 33(28):1-8.

［45］TABARI M, YAZDANI A. An energy management strategy for a DC distribution system for power system integration of plug-in electric vehicles［J］. IEEE Transactions on Smart Grid, 2016, 7(2):659-668.

［46］TARIQ M, MASWOOD A I, GAJANAYAKE C J, et al. Battery integration with more electric aircraft DC distribution network using phase shifted high power bidirectional DC-DC converter［C］// Power and Energy Engineering Conference. Brisbane, Australia: IEEE, 2015.

［47］NILSSON D, SANNINOA. Load modelling for steady-state and transient analysis of low-voltage DC systems［J］. IET Electric Power Applications, 2007, 1(5):690-696.

［48］周稳, 戴瑜兴, 毕大强,等. 交直流混合微电网协同控制策略［J］. 电力自动化设备, 2015, 35(10):51-57.

ZHOU Wen, DAI Yuxing, BI Daqiang, et al. Coordinative control strategy for hybrid AC-DC microgrid［J］. Electric Power Automation Equipment,2015, 35(10):51-57.

［49］NASIRIAN V, MODARES H, LEWIS F L, et al. Active loads of a microgrid as players in a differential game［C］// Resilient Control Conference. Philadelphia, Pennsylvania: IEEE, 2015: 1-6.

［50］POURMOUSAVI S A, NEHRIR M H, COLSON C M, et al. Real-time energy management of a stand-alone hybrid wind-microturbine energy system using particle swarm optimization［J］. IEEE Transactions on Sustainable Energy, 2010, 1(3): 193-201.

［51］KANCHEV H, LU D, COLAS F, et al. Energy management and operational planning of a microgrid with a PV-based active generator for smart grid applications［J］. IEEE Transactions on Industrial Electronics, 2011, 58(10): 4583-4592.

［52］TELEKE S, BARAN M E, BHATTACHARYA S, et al. Rule-based control of battery energy storage for dispatching intermittent renewable sources［J］. IEEE Transactions on Sustainable Energy, 2010, 1(3): 117-124.

［53］LIU X, WANG P, LOH P C. A hybrid AC/DC microgrid and its coordination control［J］. IEEE Transactions on Smart Grid, 2011, 2(2): 278-286.

［54］JIN C, LOH P C, WANG P, et al. Autonomous operation of hybrid AC-DC microgrids［C］//2010 IEEE International Conference on Sustainable Energy Technologies (ICSET). Kandy: IEEE, 2010: 1-7.

［55］GUERRERO J M, CHANDORKAR M, LEE T L, et al. Advanced control architectures for intelligent microgrids, part I: decentralized and hierarchical control［J］. IEEE Transactions on Industrial Electronics, 2013, 60(4): 1254-1262.

［56］DING G, GAO F, ZHANG S, et al. Control of hybrid AC/DC microgrid under islanding operational conditions［J］. Journal of Modern Power Systems and Clean Energy, 2014, 3(2): 223-232.

［57］EGHTEDARPOUR N, FARJAH E. Power control and management in a hybrid AC/DC microgrid［J］. IEEE Transactions on Smart Grid, 2014, 5(3): 1494-1505.

［58］HOSSEINZADEH M, SALMASI F R. Power management of an isolated hybrid AC/DC micro-grid with fuzzy control of battery banks［J］. IET Renewable Power Generation, 2015, 9(5): 484-493.

［59］QI W, LIU J, CHRISTOFIDES P D. Distributed supervisory predictive control of distributed wind and solar energy systems［J］. IEEE Transactions on Control Systems Technology, 2013, 21(2): 504-512.

［60］POURMOUSAVI S A, NEHRIR M H, COLSONC M, et al. Real-time energy management of a stand-alone hybrid wind-microturbine energy system using particle swarm optimization［J］. IEEE Transactions on Sustainable Energy, 2010, 1(3): 193-201.

［61］SEENUMANI G, SUN J, PENG H. Real-time power management of integrated power systems in all electric ships leveraging multi time scale property［J］. IEEE Transactions on Control Systems Technology, 2012, 20(1): 232-240.

［62］PALMA-BEHNKE R, BENAVIDES C, LANAS F, et al. A microgrid energy management system based on the rolling horizon strategy［J］. IEEE Transactions on Smart Grid, 2013, 4(2): 996-1006.

［63］SECHILARIU M, WANG B C, LOCMENT F. Supervision control for optimal energy cost management in DC microgrid: Design and simulation［J］. International Journal of Electrical Power & Energy Systems, 2014(58): 140-149.

［64］RIFFONNEAU Y, BACHA S, BARRUEL F, et al. Optimal power flow management for grid connected PV systems with batteries［J］. IEEE Transactions on Sustainable Energy, 2011, 2(3): 309-320.

［65］ZHANG L, LI Y. Optimal energy management of wind-battery hybrid power system with two-scale dynamic programming［J］. IEEE Transactions on Sustainable Energy, 2013, 4(3): 765-773.

［66］GUPTA A, SAINI R P, SHARMA M P. Steady-state modelling of hybrid energy system for off grid electrification of cluster of villages［J］. Renewable Energy, 2010, 35(2): 520-535.

［67］MORAIS H, KADAR P, FARIA P, et al. Optimal scheduling of a renewable micro-grid in an isolated load area using mixed-integer linear programming［J］. Renewable Energy, 2010, 35(1): 151-156.

［68］HOSSEINZADEH M, SALMASI F R. Robust optimal power management system for a hybrid AC/DC micro-grid［J］. IEEE Transactions on Sustainable Energy, 2015, 6(3):1-13.

［69］李鹏, 于晓蒙, 赵波. 基于混合灵敏度的交直流混合微网交直流断面电压H_∞鲁棒控制［J］. 中国电机工程学报, 2016, 36(1):68-75.

LI Peng, YU Xiaomeng, ZHAO Bo.H_∞ robust voltage control of AC-DC interface based on mixed sensitivity in AC-DC hybrid micogrid［J］. Proceedings of the CSEE, 2016, 36(1):68-75.

［70］WU T F, KUO C L, LIN L C, et al. DC-Bus voltage regulation for a DC distribution system with a single-phase bidirectional inverter［J］. IEEE Journal of Emerging & Selected Topics in Power Electronics, 2015, 4(1):1-1.

［71］SALOMONSSON D, SODER L, SANNINO A. Protection of low-voltage DC microgrids［J］. IEEE Transactions on Power Delivery, 2009, 24(3): 1045-1053.

［72］PAUL D. DC traction power system grounding［J］. IEEE Transactions on Industry Applications, 2002, 38(3): 818-824.

［73］JAYAWARNA N, JENKINS N, BARNES M, et al. Safety analysis of a microgrid［C］//2005 International Conference on Future Power Systems. Amsterdam, Netherlands: IEEE, 2005:1-7.

［74］IEC． Low-voltage electrical installations-Part 1：Fundamental principles，assessment of general characteristics，definitions： IEC 60364-1 ［S］．Geneva ：IEC，2005．

［75］李露露，雍静，曾礼强，等．低压直流双极供电系统的接地型式研究［J］．中国电机工程学报，2014，34(13)：2210-2218．

LI Lulu, YONG Jing, ZENG Liqiang, et al. Researches on grounding types of low-voltage DC bipolar distribution systems［J］. Proceedings of the CSEE, 2014, 34(13):2210-2218.

［76］韩奕,张东霞. 含逆变型分布式电源的微网故障特征分析［J］.电网技术,2011,35(10):147-152.

HAN Yi, ZHANG Dongxia. Fault analysis of microgrid composed by inverter-based distributed generations［J］. Power System Technology, 2011, 35(10):147-152.

［77］陆健,牟龙华.实用化的微网单相接地短路故障识别［J］.电力系统保护与控制,2012,40(11):11-15.

LU Jian, MU Longhua. A practical identification for single-phase ground fault of microgrid［J］. Power System Protection and Control, 2012,40(11):11-15.

［78］邰能灵，冯希科. 分布式电源对配电网自动重合闸的影响研究［J］. 电力科学与技术学报，2010，25 (1)：21-23.

TAI Nengling, FENG Xike. Distributed generation impact to distribution networks auto-reclosing［J］. Journal of Electric Power Science & Technology, 2010，25 (1)：21-23.

［79］FARHADI M, MOHAMMED O A. A new protection scheme for multi-bus DC power systems using an event classification approach［C］//Industry Applications Society Annual Meeting, 2015 IEEE. Dallas, Texas: IEEE, 2015: 1-7.

［80］FLETCHER S D A, NORMAN P J, GALLOWAYS J, et al. Optimizing the roles of unit and non-unit protection methods within DC microgrids［J］. IEEE Transactions on Smart Grid, 2012, 3(4): 2079-2087.

［81］REDFERN M A, AL-NASSERIH. Protection of micro-grids dominated by distributed generation using solid state converters［C］//Developments in Power System Protection, 2008. DPSP 2008. IET 9th International Conference on. Glasgow, Scotland: IET, 2008: 670-674.

［82］李武华, 顾云杰, 王宇翔,等. 新能源直流微网的控制架构与层次划分［J］. 电力系统自动化, 2015, 39(9) :156-163.

LI Wuhua, GU Yunjie, WANG Yuxiang, et al. Control architecture and hierarchy division for renewable energy DC microgrids［J］. Automation of Electric Power Systems, 2015, 39(9):156-163.

［83］郝雨辰, 吴在军, 窦晓波,等. 多代理系统在直流微网稳定控制中的应用［J］. 中国电机工程学报, 2012, 32(25):27-35.

HAO Yuchen, WU Zaijun, DOU Xiaobo, et al. Application of multi-agent systems to the DC microgrid stability control［J］. Proceedings of the CSEE, 2012, 32(25):27-35.

［84］李智诚，和敬涵，王小君，等．直流微电网的故障分析与保护配置研究［J］．北京交通大学学报，2015，39(2)：62-68．

LI Zhicheng, HE Jinghan, WANG Xiaojun, et al. Research on fault analysis and protection configuration of DC microgrid［J］. Journal of Beijing Jiaotong University, 2015, 39(2):62-68.

[1]	汤吉鸿, 章德, 丛凡超, 田国梁, 吴贵烘, 李宇骏, 禹海峰. 基于线性二次型最优控制的多端直流最优功率调制方案[J]. 电力建设, 2020, 41(8): 32-39.
[2]	赵洱岽, 王浩, 林弘杨. 现货市场中基于演化博弈的火电企业阶梯报价策略[J]. 电力建设, 2020, 41(8): 68-71.
[3]	张楷，邱晓燕，李凌昊，张浩禹，赵有林，刘梦依. 含风电系统中计及静态电压稳定影响的储能系统配置方案[J]. 电力建设, 2020, 41(7): 110-116.
[4]	宋建，束洪春，董俊，梁雨婷，李雨龙，杨博. 基于GM(1，1)与BP神经网络的综合负荷预测[J]. 电力建设, 2020, 41(5): 75-80.
[5]	祁兵，叶欣，李彬，陈宋宋，李源非，石坤. 考虑IEC标准的用户侧电力物联网体系架构研究[J]. 电力建设, 2020, 41(5): 92-99.
[6]	钟永洁，谢东亮，孙永辉，翟苏巍，常福刚，张明理. 考虑能源子系统与储能的综合能源系统优化分析[J]. 电力建设, 2019, 40(8): 59-68.
[7]	杨军，林洋佳，陈杰军，李逸欣，詹祥澎. 未来城市共享电动汽车发展模式[J]. 电力建设, 2019, 40(4): 49-59.
[8]	江帆，杨洪耕. 基于选择性贝叶斯分类的非侵入式负荷识别方法[J]. 电力建设, 2019, 40(2): 94-.
[9]	刘中原，王维庆，王海云，袁成玉，王亮，李永钦，丁文彬. 基于VSG技术的VSC-HVDC输电系统受端换流器控制策略[J]. 电力建设, 2019, 40(2): 100-.
[10]	林伟芳，易俊，贾俊川，王安斯，余芳芳，方诗卉. 故障后半波长输电线路的稳态过电压控制措施[J]. 电力建设, 2019, 40(2): 109-.
[11]	朱永强，张泉，刘康，王植，韩民晓. 交直流混合微电网互联变流器新型控制策略[J]. 电力建设, 2019, 40(11): 48-54.
[12]	朱永强，刘康，张泉，田源，蔡冰倩，夏瑞华. 考虑储能系统调度的交直流混合微电网中互联变流器容量配置[J]. 电力建设, 2019, 40(10): 84-93.
[13]	崔树银，陆奕，常啸. 考虑信用评分机制的电力碳排放交易区块链模型[J]. 电力建设, 2019, 40(1): 104-111.
[14]	朱永强, 王福源，赵娜，贾利虎. 主从控制混合微电网中互联变流器控制策略[J]. 电力建设, 2018, 39(8): 102-110.
[15]	黄裕春，王宏，王珂，文福拴. 考虑电动汽车充电设施接入的居民配电系统供电容量最优规划[J]. 电力建设, 2018, 39(6): 1-.