Wind Power and Pumped Storage Power Joint Operation Benefits Evaluation Model Based on Life-Cycle Theory

Lei Sun; Huan Huan Li; Pu Yu He; Zhong Fu Tan

doi:10.4028/www.scientific.net/AMR.902.453

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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 902Wind Power and Pumped Storage Power Joint...

Wind Power and Pumped Storage Power Joint Operation Benefits Evaluation Model Based on Life-Cycle Theory

Abstract:

Based on Life-cycle analysis theory, this paper established a wind, thermal and pumped storage power joint operation benefits evaluation model. The life cycle of energy generation joint operation is divided into four stages, including initial investment, project construction, operation and residual value recovery stages.The participation of hydro power generation can increase the amount of wind power generation and network capacity, and reduce thermal power generation amount.It can reduce abandoned wind, improving wind farm income and reduce coal consumption and pollutant emissions at the same time, and reducing the cost of purchasing electricity of the grid.

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Periodical:

Advanced Materials Research (Volume 902)

Pages:

453-456

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.902.453

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Online since:

February 2014

Authors:

Lei Sun, Huan Huan Li*, Pu Yu He, Zhong Fu Tan

Keywords:

Energy Saving, Joint Operation, Life Cycle Theory, Wind Power

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* - Corresponding Author

References

[1] Zhu Lingzhi, Chen Ning, Han Hualing. Key Problems and Solutions of Wind PowerAccommodation. [J]. Automation of Electric Power System, 2011, 22: 29-34.

Google Scholar

[2] Liu Xindong, Fang Ke, Chen Huanyuan. Research on rational wind power casting theory for large-scale wind power integration improvement. [J]. Power System Protection and Control, 2012, 06: 35-39.

Google Scholar

[3] XieChunhuai, GaoChangzheng, Li Yingying. Optimization Analysis of Wind and ThermalPower Joint Operation . [J]. Coal Technology, 2011, 12: 275-277.

Google Scholar

[4] ShenYangshuo, Chen Zhihong, Ju Liwei. Optimization Model of Wind Power and Thermal Power Jointly Operation under Energy-saving Dispatching Environment. [J]. Water Resource and Power, 2013, 05: 235-238.

Google Scholar

[5] Hu Zechun, Ding Huajie, Kong Tao. Wind power andpumped storage power stationjoint optimization ofthe daily operation ofthe model. [J]. Automation of Electric Power System, 2012, 02: 36-41+57.

Google Scholar

[6] Li Qiang, Yuan Yue, Li Zhenjie. Research on Energy Shifting Benefits of Hybrid Wind Power andPumped Hydro Storage System Considering Peak-Valley Electricity Price. [J]. Power System Technology, 2009, 06: 13-18.

Google Scholar

[7] HibiSohei. Life cycle cost assessment method - method and case[M]. Machinery Industry Press. (1984).

Google Scholar