直驱风电场经MMC-HVDC并网送端系统稳定性分析及振荡抑制

基于模块化多电平换流器MMC(modular multilevel converter)的高压直流输电HVDC(high voltage direct current transmission)因具有无源网络支撑等优势而被广泛应用于大容量新能源外送消纳。受电力电子设备交互作用等因素影响,送端系统易发生振荡失稳现象。首先,建立了直驱风电场经MMC-HVDC并网送端系统的小扰动线性化模型,分析了风场有功输出对系统稳定性的影响。然后,建立了MMC及风机并网变流器交流侧dq阻抗模型,从阻抗角度揭示了送端系统振荡失稳机理。进一步,提出了基于MMC交流电压控制外环q轴附加阻尼的振荡抑制策略,可满足系统满功率范围内的运行稳定性要求。最后,基于全比例模型的仿真结果验证了所提振荡抑制策略的有效性。

MMC-HVDC系统直流侧非金属性短路故障电流计算方法

为研究基于模块化多电平换流器的高压直流输电(MMC-HVDC)系统直流侧短路电流的工程实用计算方法,基于金属性短路故障电流通用解析式,分析了MMC-HVDC系统发生非金属性短路故障时换流站放电电流的相互抑制作用以及放电回路的耦合机理,并基于所推导的解析表达式提出了故障电流的解耦计算方法。基于PSCAD/EMTDC对MMC-HVDC系统发生非金属性短路故障工况进行仿真分析,将仿真结果与解析计算值进行对比验证。搭建数字-物理混合仿真实验模型,在数字端和物理端分别设置短路故障,对比实验值与解析计算值。验证结果表明,所提故障电流计算方法能准确地表征MMC-HVDC系统直流侧非金属性短路故障电流的演变趋势。

DC Traction Power Supply System Based on Modular Multilevel Converter Suitable for Energy Feeding and De-icing

A novel DC traction power supply system suitable for energy feeding and de-icing is proposed in this paper for an urban rail transit catenary on the basis of the full bridge submodule (FBSM) modular multilevel converter (MMC). The FBSM-MMC is a novel type of voltage source converter (VSC) and can directly control the output DC voltage and conduct bipolar currents, thus flexibly controlling the power flow of the urban rail transit catenary. The proposed topology can overcome the inherent disadvantages of the output voltage drop in the diode rectifier units, increase the power supply distance and reduce the number of traction substations. The flexible DC technology can coordinate multiple FBSM-MMCs in a wide area and jointly complete the bidirectional control of catenary power flow during the operation of the electric locomotive, so as to realize the local consumption and optimal utilization of the recovered braking energy of the train. In addition, the FBSM-MMCs can also adjust the output current when the locomotive is out of service to prevent the catenary from icing in winter. The working modes of the proposed topology are illustrated in detail and the control strategy is specially designed for normal locomotive operations and catenary de-icing. Simulation cases conducted by PSCAD/EMTDC validate the proposed topology and its control strategy.

基于源网限流贡献度配合的MMC-HVDC系统自适应故障限流策略

故障限流是保障直流输电系统安全运行的关键技术,现有源侧和网侧限流方法通常独立配置且未与故障严重程度相匹配,难以兼顾限流能力与设备成本。针对上述问题,该文提出一种考虑故障严重程度的源网自适应限流策略,利用源侧模块化多电平换流器(modular multilevel converter,MMC)与网侧故障限流器(fault current limiter,FCL)的限流贡献度配合,实现主动匹配限流目标和故障条件的自适应限流。能够在保障限流能力的前提下,降低FCL配置成本及MMC降压运行对电网的不利影响。首先,分别定量分析源侧MMC与网侧FCL的限流贡献度,进而推导考虑限流贡献度配合的源网协同限流计算方法;基于此提出限流贡献度匹配故障严重程度的自适应故障限流策略;最后,在电磁暂态仿真中对所提策略的有效性进行验证。

双U/f下垂控制下双极MMC-HVDC系统交流阻抗建模及稳定性分析

基于模块化多电平换流器的高压柔性直流输电系统(modular multilevel converter-based high voltage direct current,MMC-HVDC)常采用双极接线方式以提高系统功率输送能力和可靠性。然而目前对于风电场经柔直外送系统的稳定性研究集中于单极接线方式,孤岛直驱风电场与采用不同双极协调控制的双极MMC-HVDC互联系统小信号稳定性问题还有待进一步探究。该文首先考虑频率耦合特性、参考系初相位和直流侧耦合特性的影响,分别建立了采用双U/f下垂控制和定U/f-P/Q控制的双极MMC-HVDC系统交流侧等效SISO阻抗模型,并详细分析了金属回线阻抗和双极间功率均分度对交流阻抗特性的影响。接着对比研究了两种协调控制中共有控制环路和特有控制环路对交流侧负电阻特性及互联系统稳定性的影响规律。最后,孤岛直驱风电场经两种双极协调控制下双极MMC-HVDC外送系统Matlab/Simulink时域仿真结果和硬件在环半实物实时仿真实验结果验证了所提出的小信号阻抗模型的精确性和稳定性分析结论的有效性。

Currentless Multiple Switch Open-Circuit Faults Diagnosis for Modular Multilevel Converters with Nearest Level Modulation in HVDC Systems

Due to the large number of submodules(SMs),and modular multilevel converters(MMCs)in high-voltage applications,they are usually regulated by the nearest level modulation(NLM).Moreover,the large number of SMs causes a challenge for the fault diagnosis strategy(FDS).This paper proposes a currentless FDS for MMC with NLM.In FDS,the voltage sensor is relocated to measure the output voltage of the SM.To acquire the capacitor voltage and avoid increasing extra sensors,a capacitor voltage calculation method is proposed.Based on the measurement of output voltages,the faults can be detected and the number of different-type switch open-circuit faults can be confirmed from the numerous SMs in an arm,which narrows the scope of fault localization.Then,the faulty SMs and faulty switches in these SMs are further located without arm current according to the sorting of capacitor voltages in the voltage balancing algorithm.The FDS is independent of the arm current,which can reduce the communication cost in the hierarchical control system of MMC.Furthermore,the proposed FDS not only simplifies the identification of switch open-circuit faults by confirming the scope of faults,but also detects and locates multiple different-type faults in an arm.The effectiveness of the proposed strategy is verified by the simulation results.

双馈直驱风机混合接入MMC-HVDC送端系统的次同步振荡特性分析与抑制

双馈/直驱风机混合接入模块化多电平高压直流输电(modular multi-level converter based HVDC,MMC-HVDC)的次同步振荡事件频繁发生,已有双馈或直驱某一种风机与MMC-HVDC交互产生振荡的研究,但鲜有针对双馈/直驱风机混合接入MMC-HVDC的次同步振荡分析与抑制措施研究。该文首先阐述并分析了某双馈/直驱风机混合接入MMC-HVDC后发生次同步振荡实际事件的特征与原因,通过阻抗相量方法研究了双馈/直驱风机频域阻抗的交互影响方式。研究表明,在双馈或直驱风机单独接入MMC-HVDC不存在振荡风险的条件下,双馈和直驱风机并联接入后依然可能存在振荡风险。最后,根据电网调度运行的实际要求,提出了考虑机组启停数量调配的临时抑制振荡策略。

基于阻抗法的MMC-HVDC并网系统高频振荡分析及抑制研究

针对某海上风电经多模块多电平换流器(MMC)接入电网系统,陆上换流站与电网发生宽频振荡的问题,基于阻抗分析的思想和MMC控制系统结构建立dq坐标下MMC控制系统频域模型。将MMC控制系统模型的d、q耦合部分转换至时域、abc坐标系下进行化简,实现了系统解耦,然后建立MMC控制系统abc坐标下的频域模型,进而结合MMC等效电路的分析建立其等效阻抗模型。通过阻抗分析法对换流器阻抗模型和电网阻抗模型的特性进行分析,验证了振荡发生的机理。最后对抑制宽频振荡的措施进行分析,给出附加带阻滤波器的解决方案,并通过现场案例的振荡现象进行验证。

中小容量VSC-HVDC在解决电力系统电磁环网问题的应用

电磁环网可以提高电网供电可靠性,但也会造成故障后短路电流增加、线路过载等问题。南方电网公司目前主要采取解环运行和方式预控的措施来降低电磁环网运行风险,但解环不适用于所有场景,方式预控又可能造成电源出力受限。因此提出将中小容量柔性直流输电系统(VSC-HVDC)应用于含电磁环网的低压电网,利用其灵活可控的特点来降低电磁环网运行风险。首先综合考虑《电力系统安全稳定导则》要求以及经济性确定VSC-HVDC在电磁环网中的接入位置和容量,随后给出了VSC-HVDC直流电压、拓扑结构以及参数的确定原则。其次,设计了VSC-HVDC在电磁环网中的控制策略,该控制策略可以降低网损,提高电磁环网稳定性。最后通过实例仿真验证了提出的中小容量柔性直流方案在降低电磁环网运行风险方面的有效性。

Phasor Analytical Model of Non-isolated DC/DC Converter Based on Modular Multilevel Converter for DC Transmission Grids

Non-isolated DC/DC converter based on modular multilevel converter(MMC)technology is expected to play an important role in future DC transmission grids.This paper presents a phasor analytical model for this new family of converters which is suitable for a range of studies like DC grid power flow or DC/DC parametric design.The 30th-order phasor model is derived in 3 coordinate frames:zero sequence(DC),fundamental frequency(dq),and double frequency(d2q2).The second-harmonic current suppression control is included as an option.Additionally,an estimation of the required control signals is presented,and a closed-loop model is developed which facilitates direct calculation of all variables and fast parametric studies.The accuracy of the proposed models is verified against a detailed PSCAD model for a wide range of parameters.The studies illustrate the importance of the second-harmonic components on the model accuracy.Finally,the impact of the converter parameters on the performance is studied,and a basic eigenvalue stability analysis is given.

Single-ended Fault Detection Scheme Using Support Vector Machine for Multi-terminal Direct Current Systems Based on Modular Multilevel Converter

This paper proposes a single-ended fault detection scheme for long transmission lines using support vector machine(SVM)for multi-terminal direct current systems based on modular multilevel converter(MMC-MTDC).The scheme overcomes existing detection difficulties in the protection of long transmission lines resulting from high grounding resistance and attenuation,and also avoids the sophisticated process of threshold value selection.The high-frequency components in the measured voltage extracted by a wavelet transform and the amplitude of the zero-mode set of the positive-sequence voltage are the inputs to a trained SVM.The output of the SVM determines the fault type.A model of a four-terminal DC power grid with overhead transmission lines is built in PSCAD/EMTDC.Simulation results of EMTDC confirm that the proposed scheme achieves 100%accuracy in detecting short-circuit faults with high resistance on long transmission lines.The proposed scheme eliminates mal-operation of DC circuit breakers when faced with power order changes or AC-side faults.Its robustness and time delay are also assessed and shown to have no perceptible effect on the speed and accuracy of the detection scheme,thus ensuring its reliability and stability.

High-frequency Resonance Analysis and Impedance Reshaping Control of MMC-HVDC System Based on Frequency Coupling Impedance Model

In recent years, high-frequency resonance (HFR) events occurred in several modular multilevel converter based high-voltage direct current (MMC-HVDC) projects. The time delay of an MMC-HVDC system is the critical factor that induces HFR. The frequency coupling affects the impedance characteristics of an MMC and further deteriorates system stability. Therefore, in this paper, a multi-input multi-output admittance model of an MMC-HVDC system is developed to analyze its frequency characteristics. The effects of current loop, power loop, phase-locked loop, and operating point on the MMC frequency coupling degree are analyzed in detail. Meanwhile, to further suppress HFR in the MMC-HVDC system, an enhanced impedance reshaping control strategy based on the equivalent single-input single-output impedance model is proposed. Finally, the accuracy of the enhanced impedance model and the effectiveness of the impedance reshaping control are verified by electromagnetic transient simulations in PSCAD.

分网接入方式下LCC-HVDC系统运动方程模型及交互振荡模式的阻尼特征(一):扰动传递路径分解

与常规直流相比,永富直流逆变站存在功率全送和功率分送运行方式,而其处于分网接入方式时电网换相换流器高压直流输电(line commutated converter based high voltage directcurrent,LCC-HVDC)系统的交互振荡模式及特征尚不明确。针对这一特殊运行方式,采用模块化建模的思路建立可以反映系统电气/控制回路间交互耦合路径的运动方程模型。在此基础上,依据系统整流侧-逆变侧、正极-负极间的交互耦合路径分解得到影响系统主导模式稳定性的3条扰动传递路径,即整流侧内部自稳性路径、逆变侧内部自稳性路径、双极交互作用致稳性路径。最后,设置不同工况下的案例,量化评估不同作用路径提供的阻尼大小,并通过仿真验证运动方程模型及扰动传递路径分析结果的正确性,为后续研究分网接入方式下LCC-HVDC系统交互振荡模式的阻尼特征提供模型基础。

Modeling,Control,and Protection of Modular Multilevel Converter-based Multi-terminal HVDC Systems:A Review

Multi-terminal direct current(MTDC)grids provide the possibility of meshed interconnections between regional power systems and various renewable energy resources to boost supply reliability and economy.The modular multilevel converter(MMC)has become the basic building block for MTDC and DC grids due to its salient features,i.e.,modularity and scalability.Therefore,the MMC-based MTDC systems should be pervasively embedded into the present power system to improve system performance.However,several technical challenges hamper their practical applications and deployment,including modeling,control,and protection of the MMC-MTDC grids.This paper presents a comprehensive investigation and reference in modeling,control,and protection of the MMC-MTDC grids.A general overview of state-of-the-art modeling techniques of the MMC along with their performance in simulation analysis for MTDC applications is provided.A review of control strategies of the MMC-MTDC grids which provide AC system support is presented.State-of-the art protection techniques of the MMCMTDC systems are also investigated.Finally,the associated research challenges and trends are highlighted.

一种新型的高压直流输电技术--MMC-HVDC

介绍了模块化多电平换流器型高压直流输电(MMC-HVDC)的基本结构、工作原理和技术特点,比较了MMC-HVDC相对于电压源换流器型高压直流输电(VSC-HVDC)的优势;对MMC-HVDC目前在国内外的研究进展和工程应用情况进行了回顾,分析了MMC-HVDC技术的不足之处和未来发展中可能的重点方向,包括主电路拓扑的相关问题研究、系统设计、故障保护、接地、谐波和损耗等,指出目前研究所采用的MMC-HVDC分析模型精度较低;因自身拓扑限制,目前成熟的VSC-HVDC控制方法无法直接用于MMC-HVDC;MMC-HVDC拥有较强的故障保护能力,当前研究着重于故障仿真分析,亟待探讨适合工程应用的保护策略;由于直流侧无需安装高压电容器组,MMC-HVDC接地实现困难;由于MMC-HVDC子模块数较多,采用较低的开关频率可得到较好的输出电压波形,使得系统损耗大幅降低;最后探讨了适合我国国情的MMC-HVDC工程实践。

大型双馈风电场经MMC-HVDC并网的次同步振荡及其抑制

基于模块化多电平换流器(modular multilevel converter,MMC)的柔性直流输电技术(MMC-HVDC)已成为大规模、远距离海上风电场并网的理想解决方案。由于MMC自身的结构特点,当大型双馈风电场通过基于MMC的纯柔性直流输电系统并网时,可能会产生次同步振荡(subsynchronous oscillation,SSO)现象。该文研究了大型双馈风电场经MMC-HVDC系统并网出现的SSO现象,理论分析并推导了次同步振荡电流在MMC-HVDC系统中的分布及传播机制。从换流器控制的角度出发,提出一种基于附加次同步振荡电流抑制的送端换流站控制策略。最后通过MATLAB/Simulink软件搭建了基于21电平MMC-HVDC的两端输电系统模型,仿真结果验证了理论分析和所提出的次同步振荡电流抑制策略的正确性。

双极MMC-HVDC系统直流故障特性研究

直流故障是模块化多电平换流器高压直流输电(MMC-HVDC)的主要故障类型,目前国内外对于MMC-HVDC直流侧故障的研究主要集中于伪双极系统,而对于真双极系统直流侧故障的研究还处于起步阶段。首先,介绍真双极MMC的拓扑结构和工作原理,并根据实际交直流系统电气参数、桥臂子模块电容及电抗的放电机制,建立真、伪双极两种拓扑MMC-HVDC系统直流故障状态下的对应等效电路。然后,对比分析两种拓扑不同阶段故障电流在MMC桥臂上的流通路径,重点研究了故障短路电流对换流站桥臂阀组影响程度的差异,并指出三种电气参数与故障短路电流变化之间的内在关系。最后,基于RT-LAB仿真平台,搭建51电平双极MMCHVDC双端直流输电模型,仿真结果证明了直流故障特性研究方法的正确性。

海上风电场经MMC-HVDC并网的阻抗建模及稳定性分析

基于模块化多电平换流器(modular multilevel converter,MMC)的柔性直流输电技术(MMC-HVDC)已成为大规模、远距离海上风电场并网的理想解决方案。但是由于MMC自身结构特点,当MMC-HVDC接入风电场时有可能发生振荡或不稳定现象。该文建立MMC的交流侧小信号阻抗模型,根据最小阻抗环增益的奈奎斯特(Nyquist)稳定性判据判断互联系统的稳定性,并预测系统潜在的谐振频率及稳定裕度。研究结果表明,适当的环流控制能够显著改善MMC的稳定性。基于Matlab/Simulink建立了21电平MMC及风电场的详细时域仿真模型,仿真结果和实际工程现场录波验证了理论分析的正确性。

MMC-HVDC联网及孤岛运行状态转换策略

模块化多电平换流器型直流输电系统(modular multilevel converter based high voltage direct current,MMCHVDC)和交流线路可为重要负荷双路供电,因此MMCHVDC需具备在联网运行状态和孤岛运行状态间稳定转换的能力。该文分析了MMC在联网状态和孤岛状态间相互转换的过程,并设计了一种基于本地电气量的MMC控制模式切换策略。之后,对MMC无源供电控制器进行改进,设计了一种无需切换控制模式的MMC下垂控制策略。最后,通过PSCAD仿真对上述2种转换策略进行验证和比较,结果表明2种策略均能使MMC在联网状态和孤岛状态间稳定转换。2种策略各有优缺点,实际应用中MMC需依据具体的控制目标选取合适的策略。

一种具有故障隔离能力的MMC-HVDC换流站子模块拓扑研究

针对典型半桥型模块化多电平换流器(MMC)无法阻断直流短路故障电流的固有缺陷,提出一种串联型双电容箝位型子模块,并结合传统半桥型子模块,设计成混联型桥臂拓扑,采用更低额定工作电压的IGBT,实现子模块基本功能的同时,增加了故障电流隔离能力。与全桥子模块结构和箝位双子模块结构相比,所提出的子模块拓扑方案进一步降低了器件成本。详细描述了该方案故障电流阻断机理,并通过电磁暂态仿真模型验证了基于该子模块拓扑的换流站方案的可行性。