<trans-title>Design of Centralized Control System for Wind-light-battery Power Plants

Limin CAI; Ye HE; Tingjun ZHANG; Qiaobian WU; Guohua LIU

doi:10.16516/j.gedi.issn2095-8676.2020.S2.010

SOUTHERN ENERGY CONSTRUCTION > 2020 > 7(S2): 62-67. > DOI: 10.16516/j.gedi.issn2095-8676.2020.S2.010 CSTR: 32391.14.j.gedi.issn2095-8676.2020.S2.010

Limin CAI, Ye HE, Tingjun ZHANG, Qiaobian WU, Guohua LIU. Design of Centralized Control System for Wind-light-battery Power Plants[J]. SOUTHERN ENERGY CONSTRUCTION, 2020, 7(S2): 62-67. DOI: 10.16516/j.gedi.issn2095-8676.2020.S2.010

Citation:

Design of Centralized Control System for Wind-light-battery Power Plants

Northwest Electric Power Design Institude Co.， Ltd. of China Power Engineering Consulting Group， Xi'an 710075， China

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Received Date: June 26, 2019
Revised Date: September 01, 2019

Abstract

Abstract

Introduction The paper aims to better realize the monitoring and control of large-scale new energy centralized Internet access and improve the coordination ability between new energy base and power grid dispatching center to describe a typical scheme of wind-light-storage multi-energy complementary power centralized control system.
Method To ensure the typical scheme met the actual needs of the project， the overall scheme， system architecture， function and performance requirements of the centralized control system were studied in detail， and the relationship of the system and the traditional grid control automation system was also studied based on years of experience in power dispatching operation design.
Result The results of careful research and analysis show that the designed typical scheme of the centralized control system effectively upgrades the dispatching automation system of the new energy base.
Conclusion Our data demonstrates that the typical scheme of the centralized control system satisfies the engineering design requirements and improves the rationality and practicability of the design of the wind-light-storage multi-energy complementary power centralized control system， which can provide guidance for specific engineering applications.

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李辉

CAI Limin,HE Ye,ZHANG Tingjun,et al.Design of Centralized Control System for Wind-light-battery Power Plants[J].Southern Energy Construction,2020,07(增刊2):62-67.

References (10)

References

[1]	黄绍真，戴志强，马新平. 风电场计算机综合监控系统的设计与实现［J］. 江苏电机工程，2010，29（1）：38-40. HUANGS Z，DAIZ Q，MAX P. Design and realization of computer integrated monitoring of wind farm ［J］. Jiangsu Electrical Engineering，2010，29（1）：38-40.
[2]	王成福，李锐，刘辉荣，等. 光伏发电监控系统的设计与实现［J］. 电力系统通信，2011，32（6）：53-57. WANGC F，LIY，LIUH R，et al. The design and implementation of photovoltaic power generation monitor control system ［J］. Telecommunications for Electric Power System，2011，32（6）：53-57.
[3]	姜鑫，许伟，吴勇才. 风电场远程集中监控系统设计与实现［J］. 湖南电力，2014，34（2）：53-55. JIANGX，XUW，WUY C. Design and realization of wind farm remote centralized monitoring system ［J］. Hunan Electric Power，2014，1（2）：53-55.
[4]	陈兵，张琦兵，王昊炜，等. 规模化电网侧储能电站监控系统应用及思考［J］. 电工技术，2019，1（9）：115-118. CHENB，ZHANGQ B，WANGH W，et al. Application and thinking of large-scale monitoring system for grid side energy storage power station ［J］. Electric Engineering，2019，1（9）：115-118.
[5]	陈润泽，孙宏斌，李正烁，等. 含储热光热电站的电网调度模型与并网效益分析［J］. 电力系统自动化，2014，38（19）：1-7. CHENR Z，SUNH B，LIZ S，et al. Grid dispatch model and interconnection benefit analysis of concentrating solar power plants with thermal storage ［J］. Automation of Electric Power Systems，2014，38（19）：1-7.
[6]	赵邈，陆佳政，周任军，等. 小型风光互补并网发电系统［J］. 湖南电力，2011，31（1）：10-13. ZHAOM，LUJ Z，ZHOUR J，et al. The small-scale wind-solar hybrid grid-connected generation system ［J］. Hunan Electric Power，2011，31（1）：10-13.
[7]	唐宏德，郭家宝，陈文升. 风光储联合发电技术及其工程应用［J］. 电力与能源，2011，1（1）：61-63. TANGH D，GUOJ B，CHENW S. The joint technology of wind power-photovoltaic power-energy storage and its engineering application ［J］. Power & Energy，2011，1（1）：61-63.
[8]	石晶，龚康，刘洋，等. 复合储能在微网中的应用研究［J］. 南方能源建设，2015，2（2）：28-34. SHIJ，GONGK，LIUY，et al. Application of hybrid energy storage system in micro-grid ［J］. Southern Energy Construction，2015，2（2）：28-34.
[9]	国家能源局. 电力系统调度自动化设计规程：DL/T 5003—2017 ［S］. 北京：中国计划出版社，2017. National Energy Administration. Code for design of dispatch automation in power system：DL/T 5003—2017 ［S］. Beijing：China Planning Press，2017.
[10]	国家电力调度通信中心. 省级及以上智能电网调度技术支持系统总体设计（试行）［S］. 北京：国家电力调度通信中心，2009. China National Power Dispatching & Communication Center. Overall design of smart grid operator support system（provincial level or above）［S］. Beijing： China National Power Dispatching & Communication Center ， 2009.

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Guohua LIU

Northwest Electric Power Design Institude Co.， Ltd. of China Power Engineering Consulting Group， Xi'an 710075， China

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Design of Centralized Control System for Wind-light-battery Power Plants

Abstract