在梯级水库中建设抽水蓄能电站,为水力-风力-光伏发电系统的高质量供电提供支持

IF 9.9 1区 工程技术 Q1 ENERGY & FUELS
Zhiqiang Jing , Yimin Wang , Jianxia Chang , Xuebin Wang , Aijun Guo , Xuejiao Meng
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引用次数: 0

摘要

多能互补技术已成为推动全球能源结构转型、应对气候变化的核心要素之一。面对风电、光伏的快速增长,其发电量的不确定性将进一步增加,迫切需要探索更多类型的灵活调节电源加以弥补。在梯级水库中建设抽水蓄能电站,是扩大多能互补清洁能源基地灵活资源的可行途径。但是,这种方式使得上下水库的水力和电气连接更加复杂,给发电带来了更多的不确定性。因此,为了支持高质量的电力供应,本研究探索了清洁能源基地建设不同类型抽水蓄能电站的互补特性,并识别了巨型梯级水库的高效运行区间。首先,提出了多维度的不确定性评价体系,对风电和光伏的典型输出情景进行了详细阐述。其次,根据风电和光伏的不同利用原理,建立了水电风光互补系统、含泵站的水电风光互补系统和含可逆水轮发电机组的水电风光互补系统的多能互补运行模型。此外,还应用多维场景随机组合方法研究了重点水库运行参数与清洁能源基地运行指标之间的响应关系。最后,上述方法在黄河上游流域清洁能源基地进行了实践。主要研究成果如下:(1)当风光互补电站出力较高时,带可逆水轮发电机组的水电-风光互补系统和带泵站的水电-风光互补系统的风电和光伏消纳率分别比水电-风光互补系统提高 36% 和 12%;(2)当风光互补电站出力较高时,输电通道的负荷损失率分别比水电-风光互补系统降低 28.57% 和 14.28%。28%;(3)对于含可逆水轮发电机组的水电风光互补系统,在风电和光伏发电最大和最小情景下,关键水库综合利用流量分别保持在 500-800 m3/s 和 1000-1200 m3/s,有利于新能源的高效消纳和优质输电;(4)对于含泵站的水电风光互补系统,在风电和光伏最大和最小情景下,关键水库的综合利用流量应分别保持 500-750 m3/s 和 950-1100 m3/s。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Construction of pumped storage power stations among cascade reservoirs to support the high-quality power supply of the hydro-wind-photovoltaic power generation system
Multi-energy complementary technology has become one of the core elements to promote the structural transformation of global energy and cope with climate change. Faced with the rapid growth of wind power and photovoltaic, the uncertainty of its power generation will increase further, and it is urgent to explore more types of flexible regulation power sources to compensate for them. The construction of pumped storage power stations among cascade reservoirs is a feasible way to expand the flexible resources of the multi-energy complementary clean energy base. However, this way makes the hydraulic and electrical connections of the upper and lower reservoirs more complicated, which brings more uncertainty to the power generation. Hence, to support the high-quality power supply, this research explores the complementary characteristics of the clean energy base building different types of pumped storage power stations, and recognizes the efficient operation intervals of the giant cascade reservoir. First, a multi-dimensional uncertainty evaluation system is proposed to elaborate on the typical output scenarios of wind power and photovoltaic in more detail. Next, based on different utilization principles of wind power and photovoltaic, the multi-energy complementary operation models of the hydropower-wind-PV hybrid system, the hydropower-wind-PV hybrid system including pump stations, and the hydropower-wind-PV hybrid system including reversible hydro units are established. Further, a multi-dimensional scenarios random combination method is applied to investigate the response relationship between the operation parameters of the key reservoir and the operation indicators of the clean energy base. Finally, these above methods have been practiced in the clean energy base in the upper Yellow River basin. The main results of the research are as follows: (1) when the power output of wind-PV plants is high, the absorption rates of wind power and photovoltaic increase by 36% and 12% respectively, in hydropower-wind-PV hybrid systems with reversible hydro units and with pump stations, compared to the hydropower-wind-PV hybrid system; (2) when the power output of wind-PV plants is high, the load loss rates of the transmission channel decrease by 28.57% and 14.28% respectively, in hydropower-wind-PV hybrid systems with reversible hydro units and with pump stations, compared to the hydropower-wind-PV hybrid system; (3) for the hydropower-wind-PV hybrid system including reversible hydro units, the comprehensive utilization flow of the key reservoir respectively maintain 500-800 m3/s and 1000-1200 m3/s in the max scenario and min scenario of wind power and photovoltaic, which is beneficial to the efficient absorption of new energy and high-quality power transmission; (4) for the hydropower-wind-PV hybrid system including pump stations, the comprehensive utilization flow of the key reservoir should respectively keep 500-750 m3/s and 950-1100 m3/s in the max scenario and min scenario of wind power and photovoltaic.
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来源期刊
Energy Conversion and Management
Energy Conversion and Management 工程技术-力学
CiteScore
19.00
自引率
11.50%
发文量
1304
审稿时长
17 days
期刊介绍: The journal Energy Conversion and Management provides a forum for publishing original contributions and comprehensive technical review articles of interdisciplinary and original research on all important energy topics. The topics considered include energy generation, utilization, conversion, storage, transmission, conservation, management and sustainability. These topics typically involve various types of energy such as mechanical, thermal, nuclear, chemical, electromagnetic, magnetic and electric. These energy types cover all known energy resources, including renewable resources (e.g., solar, bio, hydro, wind, geothermal and ocean energy), fossil fuels and nuclear resources.
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