Distribution Network and Multiple Power Bi-Level Programming

Xiu Fan Ma; Li Zi Zhang

doi:10.4028/www.scientific.net/AMR.748.881

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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 748Distribution Network and Multiple Power Bi-Level...

Distribution Network and Multiple Power Bi-Level Programming

Abstract:

With the increasing application of renewable energy and clean fossil energy in the form of distributed generation in network, active load also take part in the operation of power system. Referring to the distribution network programming, it becomes more and more important to study on active load, multiply generation and distribution network coordination programming. This paper proposes a bi-level programming model to solve the problem of the coordination between the multiply generation and distribution network programming: first, treat the active load, distributed generation and centralized generation as generalized power, the cost characteristics of which decide the position in the annual load duration curve, and then work out the installations of them. Second, achieve the distribution network programming and the configuration of various types in power grid which is constrained to the results in the first layer of the programming, and aims at minimizing the investment in programming.. Modify the first programming by this result, after iteration, then we can obtain the best investment programming. In the end, take the 6-node system for example to verify the validity of this method.

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Periodical:

Advanced Materials Research (Volume 748)

Pages:

881-888

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.748.881

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Online since:

August 2013

Authors:

Xiu Fan Ma, Li Zi Zhang

Keywords:

Annual Load Duration Curve Multiple Power, Bi-Level Programming, Distributed Generation (DG), Distribution Network Programming, Generalized Power

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References

[1] Wang Caisheng, Nehrir M. Hashem: Analytical approaches for optimal placement of distributed generation sources in power systems(IEEE Transactions on Power Systems, US 2004).

DOI: 10.1109/pes.2005.1489285

Google Scholar

[2] Zhao Guobo, Liu Tianqi, Li Xingyuan: Optimal Deployment of Distributed Generation as Backup Generators(Automation of Electric Power System, China 2009).

Google Scholar

[3] Yang Yi, Wei Gang, Zhou Bing, Hu Qianyu: Planning Models and Solving Methods of Distributed Generation(Journal of　Shanghai　University　of　Electric　Power, China, 2010).

Google Scholar

[4] Luo Yunhu, Wang Bingjie, Liang Xin, Xie Shaojun: Configuration optimization of non-renewable energy distributed generation capacity(Electric Power Automation Equipment, China 2010).

Google Scholar

[5] Zhang Limei, Tang Wei, Wang Shaolin, Zhao Yunjun: Distributed Generators Planning Considering Benefits for Distribution Power Company and Independent Power Suppliers(Automation of Electric Power System, China 2011).

Google Scholar

[6] Brown Richard E., Pan Jiuping, Feng Xiaoming, et al.: Siting distributed generation to defer T&D expansion. Proceedings of the ieee power engineering society transmission and distribution conference Vol. 2(2001), pp.622-627.

DOI: 10.1109/tdc.2001.971309

Google Scholar

[7] Chen Lin, Zhong Jin, Ni Yixin, Gan Deqiang: A Study on Grid-connected Distributed Generation System Planning and Its Operation Performance(Automation of Electric Power System, China 2007).

Google Scholar

[8] Ouyang Wu, Cheng Haozhong, Zhang Xiubin etc: Distribution Network Planning Considering DG for Peak Shaving(Automation of Electric Power System, China 2008).

Google Scholar

[9] Ouyang Wu, Cheng Haozhong, Zhang Xiubin: Distributed Generation Planning Method Based on Locational Marginal Capacity Cost in Distribution Networks(Automation of Electric Power System, China 2009).

Google Scholar

[10] Qiu Xiaoyan, Xia Xiaoli, Li Xingyuan: Planning of Distributed Generation in Construction of Smart Grid(Power System Technology, China 2010).

Google Scholar

[11] Xu Yuqin, Li Xuedong, Zhang Jigang, Li Peng: Research on distribution network planning considering DGs(Power System Protection and Control, China 2011).

Google Scholar

[12] Liu Xueping, Liu Tianqi, Wang Jian: Niche-Based Multi-Objective Distributed Generators Planning in Distribution Network(Power System Technology, China 2010).

Google Scholar

[13] Zhu Yong, Yang Jingyan, Zhang Dongqing: Planning of distributed generation based on optimal real power losses(Power System Protection and Control, China 2011).

Google Scholar

[14] Ren Longxia, Lei Jinyong, Gan Deqiang: Distributed Generator Planning in Distribution Network Considering Locational/Branch Marginal Capacity Cost Model(Automation of Electric Power System, China 2010).

Google Scholar