Study on integrated development and hybrid operation mode of nuclear power plant and pumped-storage power station

The nuclear power plant is suitable for base-load operation, while the pumped-storage unit mainly gives play to capacity benefit in the electric power system;hence, the integrated development and hybrid operation mode of the two can better meet the needs of the electric power system. This article first presents an analysis of the necessity and superiority of such mode, then explains its meaning and analyzes the working routes. Finally, it proposes the business modes as follows: low price pumping water electricity plus nuclear power in the near term;nuclear power shifted to pumped storage power participating in market competition in the middle term;and, in the long term, nuclear power shifted to pumped storage power as primary and serving as an electric power system when needed.

A novel technology for control of variable speed pumped storage power plant

Variable speed pumped storage machines are used extensively in wind power plant and pumped storage power plant. This paper presents direct torque and flux control(DTFC) of a variable speed pumped storage power plant(VSPSP). By this method both torque and flux have been applied to control the VSPSP. The comparison between VSPSP's control strategies is studied. At the first, a wind turbine with the capacity 2.2 k W and DTFC control strategies simulated then a 250 MW VSPSP is simulated with all of its parts(including electrical, mechanical, hydraulic and its control system) by MATLAB software. In all of simulations, both converters including two-level voltage source converter(2LVSC) and three-level voltage source converter(3LVSC) are applied. The results of applying 2LVSC and 3LVSC are the rapid dynamic responses with better efficiency, reducing the total harmonic distortion(THD) and ripple of rotor torque and flux.

Providing Frequency Support of Hydro-Pumped Storage to Taiwan Power System with Wind Power Integration

The combination of wind and pumped storage is a useful method to compensate the fluctuation of wind power generation, which would exploit the abundant wind potential and increase wind power penetration. Taiwan Power Company (TPC) develops renewable energy actively in recent years. Moreover, TPC has started planning a high penetration wind power system and building offshore wind farms around the coast of Zhangbin, Yunlin and Penghu. The target of the offshore wind power installed capacity is up to 3 GW by 2025. However, the integration of the large scale of wind power would give huge challenges to the system operator because wind is randomly characterized. In this study, after high penetration wind power is integrated, the impacts of system frequency and the dispatch of conventional units will be discussed. Additionally, the hybrid system combing wind power with pumped-storage will be planning to reduce the effect of system frequency.

Present status of pumped hydro storage operations to mitigate renewable energy fluctuations in Japan

This paper focuses on pumped hydro energy storage(PHES)plants’current operations after electricity system reforms and variable renewable energy(VRE)installations in Japan.PHES plants have historically been developed to create electricity demand at night in order to operate base load power plants,such as nuclear power plants,in stable conditions.Therefore,many PHES plants are located midway between nuclear power plants and large demand areas.However,all nuclear power plants had to–at least temporarily–shut down after the Great East Japan Earthquake followed by a nuclear accident at Fukushima Daiichi in 2011,and renewable energy power plants have been deployed rapidly after the introduction of a feed-in-tariff(FIT)scheme.Therefore,PHES plants are being used to mitigate fluctuations of VRE,especially in areas where renewable energy has been significantly installed.The daily highest capacity ratio of PHES plants in Kyushu area has recorded three times higher than it in the other areas where the past operating mode is still conducted.But those operations on PHES plants are simply followed as a dispatch rule of the Organization for Crossregional Coordination of Transmission Operators(OCCTO),market-based operations have not been conducted enough yet.The market design shall be changed to harmonize VRE installation and PHES plants’operations are necessary to make the transition from the past operating mode of PHES plants across Japan.

基于组合赋权-云模型的抽蓄电站高质量发展评价体系

为科学评价生产期抽蓄电站高质量发展现状、把握电站发展的薄弱环节、明确建设期及新投运电站发展方向,根据抽蓄电站定位及高质量发展内涵,经过2轮筛选,构建了包含服务电力系统稳定运行、经济、绿色、创新、共享5个一级指标以及18个二级指标的评价指标体系;选用层次分析法–决策实验分析方法确定指标权重,运用云模型评价各电站高质量发展等级。最后,选取A抽蓄电站为算例验证评价体系适用性。评价结果显示,该电站服务电力系统稳定运行、绿色和共享3个指标表现均为良好,经济和创新指标表现为中等,与电站实际运行情况相符合。该验证结果表明,采用上述方法构建的评价指标体系有很好的适用性。

考虑绿证交易机制与碳捕集电厂深度调峰补偿的多主体联合调峰优化调度

为解决大规模风电不断并网引起的系统调峰负担增加问题,提出了一种考虑绿证交易机制与碳捕集电厂深度调峰补偿的碳-储-荷联合调峰双层优化方法。首先,分析了碳捕集电厂参与深度调峰成本损失,提出了深调服务补偿模型。其次,分析了绿证交易机制对碳-储-荷联合调峰的积极作用;上层以电价引导型需求响应、改善净负荷曲线平滑性程度最优为目标,旨在降低负荷峰谷差,提高风电消纳空间,缓解深度调峰机组压力;下层基于上层优化后的调峰容量,考虑绿证交易机制与碳捕集电厂深调补偿收益的碳-储联合深度调峰综合成本最优为目标,旨在发掘绿证交易机制与调峰辅助服务对深度调峰作用,发挥碳-储联合深度调峰的能力,优化系统经济性、风电消纳量、碳排放量。最后,在改进的IEEE 30节点系统进行仿真,结果验证了所提模型的有效性。

考虑灵活碳捕集电厂与抽水蓄能联合的广义经济调度策略

“双碳”背景下,灵活碳捕集电厂成为风光大规模并网后保供电和低碳化的重要过渡电源之一;然而,因其储液容量制约和风光反调峰特性造成系统在应对持续增大的负荷峰谷差时存在局限,容易造成风光流失且碳经济性不高。为此,该文引入具有双向快速功率调节能力的大容量储能-抽水蓄能,提出一种基于灵活碳捕集电厂与抽水蓄能联合的广义经济调度策略;广义经济调度综合电厂运行成本、电网净负荷经济效益、碳经济效益等多种元素。首先充分利用能耗时移特性和抽水蓄能的双倍调节能力,结合净负荷典型峰谷特征制定二者联合运行在电碳解耦下“峰互补、谷协同”机制,实现深度调峰下兼顾碳捕集和新能源消纳;进而构建电-碳市场下考虑灵活性约束等因素的广义经济成本最小为目标的调度模型,用模糊参数表征净负荷的不确定性,采用改进灰狼算法求解。仿真结果表明所提两者联合的广义经济调度策略相较于仅考虑灵活碳捕集电厂,综合成本降低25.33%,碳排放量减少18.71%,弃风弃光成本下降98.70%,验证了所提联合调度策略的优越性。

基于改进DDPG的变速抽蓄机组参与系统调频研究

在挖掘双馈型抽水蓄能(DFIM-PSH)机组调频能力的基础上,提出一种基于改进深度确定性策略梯度(DDPG)算法的系统频率控制方法。首先,基于所确定的DFIM-PSH机组在发电与抽水工况下的频率控制环节,构建考虑风电接入的含DFIMPSH单区域系统频率控制模型。其次,在考虑机组运行约束的基础上以最小化系统频率偏差及调频出力为目标,引入DDPG算法对各机组的AGC控制指令进行优化。通过在预学习中同时引入随机外部扰动与模型参数变化,提高AGC控制器在具有强不确定性环境中的适应性。最后,在仿真验证DFIM-PSH调频优势的基础上,在不同风电接入及扰动等多场景进行仿真分析,结果表明,所提频率控制方法能有效改善新型电力系统的频率特性且具有强鲁棒性。

多能互补发电系统故障识别与测距方法

随着大量新能源的接入,使得多端柔性直流系统(modular multilevel converter based multi-terminal direct current, MMC-MTDC)故障特征愈加复杂,快速准确的故障识别与测距是亟需解决的关键难题之一。为此,提出了一种风-光-储-蓄互补发电站经柔性直流输电外送系统故障识别与测距方法。首先,搭建风-光-储-蓄互补发电站经柔直外送系统,在此基础上,提出了一种Teager能量算子能量熵的新方法,利用测量点正负极Teager能量算子能量熵的比值构建故障选极及区段识别判据。接着,针对已识别的故障线路,提出变分模态分解(variational mode decomposition, VMD)与Teager能量算子(teager energy operator, TEO)相结合的故障测距方法。最后,利用PSCAD/EMTDC进行仿真,结果表明所提识别方法可以准确判断故障所在线路,所提测距方法能在故障发生2 ms时间窗内实现故障测距,误差率不超过2.55%,并具有较高的耐过渡电阻能力。

大型抽水蓄能电站长直型隧洞风尘迁移规律研究

抽水蓄能电站地下洞室群施工存在通风难度大、风尘迁移变化规律无显著特征等难题,采用DPM气固两相流模型,针对地下洞室群中不同坡度的长直型隧洞进行数值试验研究,重点揭示了典型隧洞在不同施工条件下的风尘迁移规律及小粒径沉降粉尘分布特征。研究表明:不同区域粉尘质量浓度随风机风速的增大呈下降趋势,当风速增至21 m/s时开始升高;掌子面附近区域粉尘质量浓度随供风距离的增大呈上升趋势,当供风距离大于25 m时,风机风速不再满足隧洞内通风要求;掌子面附近区域粉尘质量浓度随隧洞坡度的增大呈显著上升趋势,通风管附近出现明显的粉尘空白带;小粒径沉降粉尘分布特征由通风管位置决定,沉降粉尘颗粒最多处位于通风管出口与掌子面之间,粒径分布较广,呈正态分布规律,在通风管出口正后方处急剧下降,并沿隧洞出口方向数量逐渐减少,平均粒径逐渐减小;流出洞外的粉尘颗粒平均粒径偏小。本研究可为抽水蓄能电站地下洞室群整体施工设计提供参考。

基于NSGA-Ⅱ串行模式搜索的新能源发电与抽水蓄能电站联合系统多时间尺度优化调度方法

针对新能源发电与抽水蓄能电站联合发电系统,提出一种多时间尺度优化调度策略,并提出一种结合快速非支配排序遗传算法(NSGA-Ⅱ)和模式搜索算法的NSGA-Ⅱ-PS算法,该策略针对不同的时间尺度分别设定目标函数与约束条件,对比NSGA-Ⅱ与NSGA-Ⅱ-PS在解决本调度问题结果上的优劣性。在日前、日中时间尺度对联合系统进行优化调度,制定调度计划。结果表明:在高比例新能源消纳的基础上,新能源发电与抽水蓄能电站联合系统多时间尺度优化调度可在日前、日中尺度实现联合系统经济安全运行。

抽水蓄能电站水库岩质边坡消落带生态修复探讨

抽水蓄能电站是我国水利水电开发的重要组成部分,建成运行后将形成库水周期性涨落的消落带,生境条件极为脆弱,是生态环境修复的重难点区域。对岩质边坡生态修复关键技术和水库消落带生境改善方法开展系统分析,结合河南天池抽水蓄能电站上水库岩质边坡消落带生境特征,提出土工格室+生态袋+挂网复合工程技术可作为水库岩质边坡消落带生态治理的关键措施。基于消落带库水涨落节律和植物自身遗传特性,指出消落带下端优先配置长期耐淹多年生草本植物(如狗牙根),消落带中端配置耐淹能力较强的灌木和草本(如秋华柳、黄荆、紫穗槐、中华蚊母和狗牙根等),消落带上端可综合配置抗旱耐淹能力较好的乔木、灌木和草本(如银合欢、桑树、紫穗槐、黄荆、秋华柳、狗牙根和苘麻等),以及生态适应性较强的乡土植物(如藜和诸葛菜等)。研究成果对抽水蓄能电站水库岩质边坡消落带生态治理具有重要指导意义。

铅山抽水蓄能电站额定水头选择

水蓄能电站是顺应社会发展潮流的朝阳行业,我国大力提倡和扶持水力发电站的建设,而抽水蓄能电站额定水头的选择直接影响机组的使用效率、使用寿命及可靠性和稳定性。水轮机是一种用于发电的重要设备,其安装质量直接影响发电站的安全和运行效率。研究抽水蓄能电站额定水头是水轮机稳定运行的保障,能确保水蓄能电站安全运行。文章对抽水蓄能电站水泵水轮机额定水头的选取方法进行了探讨,进行了铅山抽水蓄能电站额定水头的选择。

湖南省桂阳抽水蓄能电站高压引水隧洞稳定性分析

为研究湖南桂阳抽水蓄能电站高压引水隧洞稳定性,在工程区开展了高压压水试验和地应力测试,定量描述了隧洞围岩在高内水压力作用下的渗透特性,分析了整个工程区特别是重要工程部位的岩体应力状态,在此基础上根据围岩条件、抗抬理论准则、最小主应力准则、渗透准则评价了高压引水隧洞的渗透稳定性。结果表明:(1)工程区水平主应力大小总体上随深度的增加而增大,3个主应力之间的关系为SH>SZ>Sh,属于走滑型应力状态,钻孔附近地壳浅表层的最大水平主应力方位平均为NW32°,高压岔管及厂房区域属中等-低地应力区。高压压水试验结果显示隧洞围岩属于弱至微透水岩体;(2)高压引水隧洞各洞段具有足够的埋深条件,满足抗抬理论准则,同时隧洞围岩的抗渗透能力及抗水力劈裂能力均较好,基本满足钢筋混凝土衬砌方案的要求。

句容抽蓄上水库筑坝料E-B模型分期反演参数对比分析

为预测句容抽蓄上水库坝体和库盆在竣工期和蓄水后产生的变形,利用施工期上库主坝和库盆的变形监测资料,对填筑料E-B模型参数进行分期反演。在此基础上,采用第三期反演参数,对竣工期和蓄水后的库盆变形特性进行预测和分析。研究表明,利用早期短时序坝体变形监测资料得到的模型反演参数偏大,随着坝体填筑高度的增加,采用后期长时序变形监测资料反演得到的模型参数逐渐减小并趋于真实值;在E-B模型中引入初始应力状态参数S0可以考虑现场压实坝料的超固结特性,S0越大,坝体变形越小,经历高强度碾压后的填筑料S0在0.40~0.55之间;基于第三期反演参数的库盆竣工期沉降计算结果与实测结果总体吻合较好。研究结果可用于指导工程实践。

Effect of dry-wet cycles on dynamic properties and microstructures of sandstone:Experiments and modelling

Underground pumped storage power plant(UPSP)is an innovative concept for space recycling of abandoned mines.Its realization requires better understanding of the dynamic performance and durability of reservoir rock.This paper conducted ultrasonic detection,split Hopkinson pressure bar(SHPB)impact,mercury intrusion porosimetry(MIP),and backscatter electron observation(BSE)tests to investigate the dynamical behaviour and microstructure of sandstone with cyclical dry-wet damage.A coupling FEM-DEM model was constructed for reappearing mesoscopic structure damage.The results show that dry-wet cycles decrease the dynamic compressive strength(DCS)with a maximum reduction of 39.40%,the elastic limit strength is reduced from 41.75 to 25.62 MPa.The sieved fragments obtain the highest crack growth rate during the 23rd dry-wet cycle with a predictable life of 25 cycles for each rock particle.The pore fractal features of the macropores and micro-meso pores show great differences between the early and late cycles,which verifies the computational statistics analysis of particle deterioration.The numerical results show that the failure patterns are governed by the strain in pre-peak stage and the shear cracks are dominant.The dry-wet cycles reduce the energy transfer efficiency and lead to the discretization of force chain and crack fields.

天台抽水蓄能电站岩壁梁爆破开挖精细化控制技术

岩壁梁具有经济可靠、方便施工、加快进度等优点,在地下厂房的建设中得到广泛使用。以浙江天台抽水蓄能电站中岩壁梁的开挖爆破施工为工程背景,基于现场爆破试验,提出了精细化爆破参数与网路设计方案,总结了现场采用的岩壁梁爆破施工精细控制方法,对比分析了各种施工措施实际应用后的现场效果与监测结果,可供类似工程参考。

季节水温变化对充水保压蜗壳承载特性的影响

抽水蓄能电站钢蜗壳一般均采用充水保压埋入方式,在正常运行过程中,蜗壳内季节水温变化将影响钢蜗壳—混凝土接触关系,继而影响充水保压蜗壳的承载特性。为此,基于运行期钢蜗壳温度监测结果,研究了运行期钢蜗壳实际温度变化情况,并采用有限元方法研究了运行期钢蜗壳—混凝土接触关系的变化规律、结构承载特性及不平衡水推力分载情况。结果表明,在机组投产后正常运行年内,钢蜗壳内季节水温变化对钢蜗壳—混凝土接触闭合时机及空间分布影响显著;夏季水温升高将导致蜗壳外包混凝土承载比显著升高,应确保混凝土配筋满足强度和正常使用要求;而在冬季水温降低时止推环将起到承担不平衡水推力的主要作用,与此同时,座环也承担了约30%~40%的不平衡水推力,说明充水保压蜗壳设置止推环和加强座环锚固非常必要。

扬程特性关联下矿井主泵排水智能控制方法研究

矿井下常常存在地下水渗积问题,通过控制主泵出水压力,能够有效地排除积水,保持井下环境相对干燥,增强煤矿地下环境的安全性。但由于矿井下的透水后压力负荷通常是不确定的,单纯以压力为传感信号的主泵排水控制的稳定性会受到较大影响,当前排水多以人工观测为主,排水控制智能化实现难度较大。提出一种扬程特性关联下矿井主泵排水智能控制方法。分析矿井下大功率变频式主泵的扬程特性(H-Q),获取变频式主泵排水压力和扬程特性(H-Q)之间的关系。利用这一关系作为传感信号,采用解耦补偿器和神经网络,利用神经网络在线调整比例、积分和微分(proportional integral derivative,PID)控制参数,组建大功率变频式主泵出水压力智能控制器,实现泵出水压力智能控制。通过实验分析证明,研究方法应用后在22 s左右矿井主泵达到最佳状态,过程中产生的相对误差均在0.5%以下。在多次迭代控制下,所提方法的控制延误始终低于0.1 ms。