Phase Balance for Integration of Distributed Photovoltaic to Smart Distribution Grids Based on IMO-SLFDA

Operations Research and Management Science ›› 2014, Vol. 23 ›› Issue (3): 209-218.

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Phase Balance for Integration of Distributed Photovoltaic to Smart Distribution Grids Based on IMO-SLFDA

ZENG Ming¹, XUE Song², SHI Hui¹, OUYANG Shao-jie¹

1. School of Economics and Management, North China Electric Power University, Beijing 102206, China;
2. State Grid Energy Research institute,Beijing 102209, China

Received:2012-10-28 Online:2014-03-25

基于IMO-SLFDA的大规模分布式光伏并网的智能配电网相位平衡研究

曾鸣¹, 薛松², 史慧¹, 欧阳邵杰¹

1.华北电力大学经济与管理学院,北京市昌平区 102206;
2.国网能源研究院,北京 102209

作者简介:曾鸣(1957-),男,山西太原人,教授,博士生导师,研究方向:能源经济和电力市场;薛松(1986-),男,山东淄博人,博士,研究方向:技术经济及管理;史慧(1990-),女,河南驻马店人,硕士,研究方向:优化理论;欧阳邵杰(1989-),男,浙江杭州人,博士,研究方向:低碳电力系统。
基金资助:
国家自然科学基金项目(71271082);国家软科学研究计划(2012GXS4B064)

Abstract

Abstract: A large amount of distributed photovoltaic accessing to smart distribution grid may lead to an imbalance in the three-phase current, and then could damage the security and stability of the distribution system. So this paper constructs a distribution multi-objective optimization model, the objectives of which are current imbalance minimization and energy loss minimization. This model aims at solving phase balance problems of distribution network after large-scale distributed PV into grid. Then, Shuffled Frog Leap Algorithm is optimized by Random Nelder Mead, improving shortcomings of SFLA. Combining it with decision algorithm, this paper proposes improved multi-objective decision-shuffled frog leaping algorithm for the numerical example. IMO-SLFDA can ensure it obtains the optimal solution in an extremely fast search speed and high accuracy. Last, this paper takes the IEEE 123-bus three phase unbalanced test system as the numerical example, and three phase balance of the distribution system is achieved by controlling the variables related operations. Making the comparative analysis of the difference between base case and optimized example, the proposed algorithm is verified, advanced and practical.

Key words: new energy management planning, shuffled frog leaping decision-making algorithm, distributed generation, smart distribution grid

摘要： 分布式光伏的大量接入智能配电网后,可能导致三相电流的失衡,进而破坏配电系统的安全稳定性。对此,本文构建了以电流不平衡和电能损失最小化为目标的含分布式光伏的配电网优化的多目标模型,旨在解决大规模分布式光伏发电并网后配电网相位平衡的问题;然后,用随机单纯形法对混合蛙跳算法进行优化,改进了蛙跳算法求解优化问题时极易陷入局部最优以及计算效率较低的缺点,并和决策算法相结合,提出适用本文算例的改进的多目标混合蛙跳决策算法,确保能以极快的搜索速度和较高的计算精度得到最优解;最后,以IEEE-123节点三相不平衡测试系统为例,通过控制变量的相关操作实现配电系统的三相平衡。对比分析基础案例和优化算例的差异,验证了本文所提算法的先进性和实用性。

关键词: 新能源管理规划, 混合蛙跳决策算法, 智能配电网, 分布式发电

CLC Number:

TM615
C931.1

ZENG Ming, XUE Song, SHI Hui, OUYANG Shao-jie. Phase Balance for Integration of Distributed Photovoltaic to Smart Distribution Grids Based on IMO-SLFDA[J]. Operations Research and Management Science, 2014, 23(3): 209-218.

曾鸣, 薛松, 史慧, 欧阳邵杰. 基于IMO-SLFDA的大规模分布式光伏并网的智能配电网相位平衡研究[J]. 运筹与管理, 2014, 23(3): 209-218.

References

[1] 王晓佳,张宝霆,徐达宇,等.含有压缩因子的粒子群优化灰色模型在智能电网中的应用[J].运筹与管理,2012,21(3):114-118.
[2] 刘小聪,王蓓蓓,李扬,等.智能电网下计及用户侧互动的发电日前调度计划模型[J].中国电机工程学报,2013,33(1):30-38.
[3] 周孝信,陈树勇,鲁宗相,等.电网和电网技术发展的回顾与展望——试论三代电网[J].中国电机工程学报,2013,(22):1-11.
[4] http://www.sgcc.com.cn/ztzl/zgtgy/mtjj/196449.shtml
[5] 陆一鸣,刘东,柳劲松,等.智能配电网信息集成需求及模型分析[J].电力系统自动化,2010,34(8):1-4,96.
[6] 贾东梨,孟晓丽,宋晓辉.智能配电网自愈控制技术体系框架研究[J].电网与清洁能源,2011,27(2):14-18.
[7] 刘伟,彭冬,卜广全,等.光伏发电接入智能配电网后的系统问题综述[J].电网技术,2009,33(19):1-6.
[8] 赵波,张雪松,洪博文,等.大量分布式光伏电源接入智能配电网后的能量渗透率研究[J].电力自动化设备,2012,32(8):95-100.
[9] Whitaker C, Newmiller J, Ropp R, et al. Distributed photovoltaic systems design and technology requirements[R]. Albuquerque, New Mexico, USA: Sandia National Laboratory, 2008.
[10] Jewell W, Ramakumar R, Hill S. A study of dispersed PV generation on the PSO system[J]. IEEE Transactions on Energy Conversion, 1988, 3(3): 473-478.
[11] 王旭东,林济铿.基于分支定界的含分布式发电配网孤岛划分[J].中国电机工程学报,2011,31(7):16-20.
[12] Ishikawa T. Grid-connected photovoltaic power systems: survey of inverter and related protection equipments[R]. Tokyo, Japan: Report IEA-PVPS Task, 2002.
[13] 陈炜,艾欣,吴涛,等.光伏并网发电系统对电网的影响研究综述[J].电力自动化设备,2013,33(2):26-32,39.
[14] 许晓艳,黄越辉,刘纯.分布式光伏发电对配电网电压的影响及电压越限的解决方案[J].电网技术,2010,34(10)140-146.
[15] 王志群,朱守真.分布式发电对配电网电压分布的影响[J].电力系统自动化,2004,28(16):56-60.
[16] 杨昌兴,赵启承,杨立川,等.并联电容器组保护起始不平衡值的估算[J].电力电容器与无功补偿,2010,3(4):30-34.
[17] Deshmukh M K, Deshmukh S S. Modeling of hybrid renewable energy systems[J]. Renewable and Sustainable Energy Reviews, 2008, 12(1): 235-249.
[18] 丁明,徐宁舟.基于马尔可夫链的光伏发电系统输出功率短期预测方法[J].电网技术,2011,35(1):152-157.
[19] 侯玉梅,刘倩,孙华宝,等.成批到达的有特殊服务时间的多重休假排队系统分析[J].运筹与管理,2006,15(4):79-84.
[20] American national standard for electric power systems and equipment-voltage ratings(60 Hertz). ANSI Standard C84.1, 1995.
[21] 张燕,周支立.供应链中的多目标经济批量排产和运送问题的求解[J].运筹与管理,2009,18(1):34-41.
[22] 刘云志,郭嗣琮.含弹性约束的多目标模糊线性规划求解[J].运筹与管理,2013,22(1):59-64.
[23] 姜昱汐,潘少华,李兴斯,等.基于Whittaker修匀的多目标修匀模型[J].运筹与管理,2012,21(3):33-38.
[24] 秦学志,魏强,胡友群,等.经济增长贡献率视角下的多目标信贷配置模型[J].运筹与管理,2012,(6):189-196.
[25] IEEE distribution planning working group report. radial distribution test feeders[J]. Transactions on Power Systems, 1991, 6(3): 975-985.
[26] Reliability test system task force of application of probability methods subcommittee. IEEE reliability test system[J]. IEEE Transactions on Power Apparatus and Systems, 1979, PAS-98(6): 2047-2054.

Phase Balance for Integration of Distributed Photovoltaic to Smart Distribution Grids Based on IMO-SLFDA

基于IMO-SLFDA的大规模分布式光伏并网的智能配电网相位平衡研究

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