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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 614-615Distributed Network Power Flow of Distributed...

Distributed Network Power Flow of Distributed Generation

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Abstract:

With constrains imposed by natural conditions, the power generated from wind power, solar power and other intermittent energy system has great randomness and volatility. Thus, the impact from the intermittent energy to the system voltage and power flow is uncertainty. In view of this problem, this paper studies the characteristics of these double random variables and correlation. By using the typical probabilistic load flow and Monte Carlo simulation method, this paper poses the probability load flow adapted to the intermittent distributed generation. Finally, taking IEEE33 distribution system for example, this paper obtains the mutual relationship between the power from the intermittent distributed generation and the probability distribution of the node voltage, current distribution of each branch.

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Advances in Power and Electrical Engineering

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Periodical:

Advanced Materials Research (Volumes 614-615)

Pages:

1693-1699

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.614-615.1693

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Online since:

December 2012

Authors:

Qi Yang, Meng Cong Liu, Ying Chen, Yun Xiao Bai

Keywords:

Intermittent Distributed Systems, Monte Carlo, Probability Load Flow

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© 2013 Trans Tech Publications Ltd. All Rights Reserved

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[1] Youwei Liang, Zhijian Hu, Yunping Chen: Power System Technology, Vol.27(2003), p.71

[2] Pei Li, Xingyuan Li: International Electric Power for China, Vol. 9(2005), p.45

[3] Abur H Singh, Liu H, Klingensmith W N: Three Phase Power Flow for Distribution Systems With Dispersed Generation. Sevilla: 14th PSCC, 2002.

[4] Zhiqun Wang, Shouzhen Zhu, Shuangxi Zhou, et al: Automation of Electric Power Systems, Vol. 28(2004), p.56

[5] Abouzbar I, Ramakumar R: An Approach to Access the Performance of Utility Interactive Wind Execrative Wind Electric Conversion Systems. IEEE Trans on Energy Conversion, Vol.6(1991), p.617

DOI: 10.1109/60.103635

[6] Yuewen Jiang, Chong Chen, Buying Wen: East China Electric Power, Vol.36(2008), p.86

[7] Caihao Liang, Xianzhong Duan: Automation of Electric Power Systems, Vol.25(2001), p.53

[8] Qi Yang, Jianhua Zhang, Zifa Liu, et al: Automation of Electric Power Systems, Vol.33(2009), p.86

[9] Ming Ding, Xuefeng Guo, et al: Proceedings of the Chinese Society for Electrical Engineering, Vol.29(2009), p.35

[10] Zongxiang Lu, Caixia Wang, Yong Min: Automation of Electric Power Systems, Vol.31(2007), p.100

[11] Caire R, Retiere N, Martina S, et al: Impact Assessment of LV Distributed Generation on MV Distribution Network. 2002 IEEE Power Engineering Society Summer Meeting, Chicago, 2002, p.1428

DOI: 10.1109/pess.2002.1043620

[12] Niknam T, Ranjabar A M, Shirani A R: Impact of Distributed Generation on Volt/Var Control in Distribution Networks．IEEE Power Tech Conference Proceedings, Bologna, 2003．

DOI: 10.1109/ptc.2003.1304390

[13] Lasseter R H, Paigi P: Microgrid: a Conceptual Solution. IEEE Power Electronic Specialists Conference，Aachen，2004．

DOI: 10.1109/pesc.2004.1354758

[14] Lasseter R, Akhil A, Marmay C, et al: Integration of Distributed Energy Resources: the Certs Microgrid Concept. http://certs. lbl.gov/pdf/50829.pdf, 2007-04-01．

DOI: 10.2172/799644

[15] Marnay C, Rubio F J, Siddiqui A S: Shape of the Microgird. http://repositories.cdlib.org/cgi/viewcontent.cgi?article=3379&context=lbnl, 2007-01-01．

[16] Hatziargyriou N, Asano H, Iranvani R, et al: IEEE Power and Energy Magazine, Vol. 5(2007), p.78

[17] Kun Sheng, Li Kong, Zhiping Qi, et al: RELAY, Vol.35(2007), p.75

[18] Changgui Wang, Rongqiang Cui, Di Zhou: New Energy Generation Technologies (In Chinese). China Electric Power Press, 2003.

[19] Jun Chen: Study on Wind/solar Hybrid Isolated Power System Isolated Power System (In Chinese). Inner Mongolia University of Technology, 2006.

[20] Chaoqun Zhu: Journal of Nanjing University, Vol. 10(1997)

[21] Chengshan Wang, Haifeng Zheng, Yinghua Xie, et al: Automation of Electric Power Systems, Vol. 29(2005), p.39

[22] Shouyi Pan: Modern Climate Principles (In Chinese). Meteorological Press, 1994.

[23] Suning Zhang, Shengyuan Tian: Acta Energiae Solaris Sinica, Vol.18(1997), p.273

[24] Parishwad C V, Bhardwaj R K, Nema V K: Renewable Energy, Vol.12(1997), p.303

[25] Ren M J, Wright J A: HVAC and Reasearch, Vol.8(2002), p.383

[26] Kimbell H H: Mon Weather Rev, Vol.47(1919), p.769

[27] Qi Yang, Jianhua Zhang, Xiangfeng Wang, et al: Power System Technology, Vol.33(2009), p.44