Engineering practices for the integration of large-scale renewable energy VSC-HVDC systems

被引：32

作者：

Li Y. ^{[1
]}

Liu H. ^{[1
]}

Fan X. ^{[2
]}

Tian X. ^{[1
]}

机构：

[1] China Electric Power Research Institute, Haidian District, Beijing

[2] College of Electrical and Electronic Engineering, North China Electric Power University, Changping District, Beijing

来源：

Global Energy Interconnection | 2020年 / 3卷 / 02期

关键词：

DC grid; Engineering practice; Renewable energy integration; VSC-HVDC;

D O I：

10.1016/j.gloei.2020.05.007

中图分类号：

学科分类号：

摘要：

With the continuous development of power electronic devices, intelligent control systems, and other technologies, the voltage level and transmission capacity of voltage source converter (VSC)-high-voltage direct current (HVDC) technology will continue to increase, while the system losses and costs will gradually decrease. Therefore, it can be foreseen that VSC-HVDC transmission technology will be more widely applied in future large-scale renewable energy development projects. Adopting VSC-HVDC transmission technology can be used to overcome issues encountered by large-scale renewable energy transmission and integration projects, such as a weak local power grid, lack of support for synchronous power supply, and insufficient accommodation capacity. However, this solution also faces many technical challenges because of the differences between renewable energy and traditional synchronous power generation systems. Based on actual engineering practices that are used worldwide, this article analyzes the technical challenges encountered by integrating large-scale renewable energy systems that adopt the use of VSC-HVDC technology, while aiming to provide support for future research and engineering projects related to VSC-HVDC-based large-scale renewable energy integration projects. © 2020

引用

页码：149 / 157

页数：8

共 42 条

[21]

Ye Y., Lu Z., Xie L., A Coordinated Frequency Regulation Strategy for VSC-HVDC Integrated Offshore Wind Farms, Paper presented at the 2018 IEEE Power & Energy Society General Meeting, Portland, OR, USA5-10 Aug 2018, (2018)

[22]

McGill R., Torres-Olguin R., Anaya-Lara O., Et al., Generator response following as a primary frequency response control strategy for VSC-HVDC connected offshore wind farms, Energy Procedia, 137, pp. 108-118, (2017)

[23]

Alassi A., Banales S., Ellabbana O., HVDC Transmission: Technology Review, Market Trends and Future Outlook, Renewable and Sustainable Energy Reviews, 112, pp. 530-554, (2019)

[24]

Guo X., Mei N., Li T., Et al., Study on solution for power surplus in Zhangbei VSC-based DC grid mechanism analysis and control method, Power System Technology, 43, 1, pp. 157-164, (2019)

[25]

Ndreko M., Popov M., van der Meijden M.A., Study on FRT compliance of VSC-HVDC connected offshore wind plants during AC faults including requirements for the negative sequence current control, International Journal of Electrical Power & Energy Systems, 85, pp. 97-116, (2017)

[26]

Gil-Gonzalez W., Montoya O.D., Garces A., Direct power control for VSC-HVDC systems: An application of the global tracking passivity-based PI approach, International Journal of Electrical Power & Energy Systems, 110, pp. 588-597, (2019)

[27]

Cao S., Xiang W., Lin W., Et al., Fault ride-through and energy dissipation control of bipolar hybrid MMC-MTDC integrating wind farms, Power System Protection and Control, 47, 7, pp. 39-48, (2019)

[28]

Ling W., Sun W., Zhang J., Et al., Analysis of typical operating modes of Zhoushan multi-terminal VSC-HVDC pilot project, Power System Technology, 40, 6, pp. 1751-1758, (2016)

[29]

Liu L., Cai X., Yu F., Et al., Zhoushan multi-terminal VSC- HVDC transmission demonstration project and its evaluation, Southern Power System Technology, 13, 3, pp. 79-88, (2019)

[30]

Guo X., Zhou Y., Mei N., Et al., Construction and characteristic analysis of Zhangbei flexible DC grid, Power System Technology, 42, 11, pp. 3698-3707, (2018)

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