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Research about Voltage Support of Distribution Network with Distributed Generation

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Abstract:

It brings all kinds of negative and positive impact on distribution network with the distributed generation connection. Feeder voltage of the distribution network will be affected. Distributed generation can play a good supporting role to the feeder voltage, which also can make feeder voltage exceed the maximum safe voltage. The details have an important relationship with the capacity, size and location of distributed generation. The voltage supporting model and voltage calculation method of distributed generation connected with distributed network is given in the paper. The IEEE 34 Node model was chosen to be discussed how different factors can influence the feeder voltage. This paper analyzes distributed generation’s influence to the distribution system voltage level.

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Periodical:

Applied Mechanics and Materials (Volumes 291-294)

Pages:

2259-2265

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.291-294.2259

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Cite this paper

Online since:

February 2013

Authors:

Ying Ying Sun

Keywords:

Distributed Generation (DG), Distribution Network, Voltage Support

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© 2013 Trans Tech Publications Ltd. All Rights Reserved

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References

[1] Liang Youwei, Hu Zhijian, Chen Yunping. A survey of distributed generation and its application in power system[J]. Power System Technology, 2003, 27(12):71-75(in Chinese).

DOI: 10.1109/icpst.2004.1459969

Google Scholar

[2] Qian Kejun, Yuan Yue. Distributed generation technology and itsimpact on power system[J] . Relay , 2007 , 35(13) : 25-28(inChinese).

Google Scholar

[3] Zhang Jiajia, Chen Jinfu, Fan Rongqi. Investigation of the influence, of micro-grids high large penetration ratios on power network stability[J]. Journal of Electric Power Science and Technology2009, 24(1):25-29(in Chinese).

Google Scholar

[4] Huang Wei, Sun Changhui, Wu Ziping, et al. A review on microgrid technology containing distributed generation system[J]. Power System Technology, 2009, 33(9):14-18(in Chinese).

Google Scholar

[5] Baran M E, El-Markabi I M. A multiagent-based dispatching scheme for distributed generators for voltage support on distribution feeders[J]. IEEE Trans on Power Systems, 2007, 22(1):52-59.

DOI: 10.1109/tpwrs.2006.889140

Google Scholar

[6] Laaksonen H, Saari P, Komulainen R. Voltage and frequency control of inverter based weak LV network microgrid[C]/2005 International Conference on Future Power Systems. Amsterdam, Netherlands:IEEE, 2005:16-18.

DOI: 10.1109/fps.2005.204293

Google Scholar

[7] Nagata T, Nakachi Y, Hatano R. A multi-agent cooperative voltage control method[C]/2008 IEEE Power&Energy Society General Meeting. Piscataway, NJ, USA:IEEE, 2008:20-24.

DOI: 10.1109/pes.2008.4596598

Google Scholar

[8] Engler A. Applicability of droops in low voltage grids[J]. DER Journal, 2005, 16(8):22-27.

Google Scholar

[9] BEGOVIC M. Sustainable Emergency Technologies and Distribution. In: Proceeding of 2001 IEEE Power Engineering Society Summer Meeting. Vol 1. Vancouver(Canada): 2001. 540 - 545.

Google Scholar

[10] N. Hadjsaid, J.F. Canard, F. Dumas. Dispersed generation impact on distribution networks [J]. IEEE Computer Applications in Power, 1999, 12(2): 22–28.

DOI: 10.1109/67.755642

Google Scholar

[11] T.E. McDermott, R.C. Dugan. Distributed generation impact on reliability and power quality indices. In:Rural Electric Power Conference. IEEE, 2002, 5-7.

DOI: 10.1109/repcon.2002.1002301

Google Scholar

[12] Ackermann T, Knyazkin V. Interaction between distributed generation and the distribution network:Operation aspects. In:Proc of IEEE Power Engineering Society Transmission and Distribution Conference. Asia Pacific, 2002, 1357-1362.

DOI: 10.1109/tdc.2002.1177677

Google Scholar

[13] Duxi Zhang, Over voltage in distribution network caused by distributed generation[D], Zhejiang University, 2007, 5.

Google Scholar

[14] tsai-Hsiang Chen, Mo-Shing Chen, Kab-ju Hwang, Paul Kotas, Elie A. Chebli. Distribution system power flow analysis: arigid approach [J]. IEEE Trans. On Power Delivery. 1991, 6(3): 1146-1152.

DOI: 10.1109/61.85860

Google Scholar

[15] Qiu Xiaoyan, Xia Lili, Li Xingyuan. Planning of distributedgeneration in construction of smart grid[J]. Power SystemTechnology, 2010, 34(4):7-10(in Chinese).

Google Scholar

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