Your search keyword '"harmonic instability"' showing total 43 results

1. 计及线路分布参数的新能源场站谐波不稳定源头定位.

Author

徐方维, 卢煜国, 郭 凯, 郑鸿儒, 舒 勤, 马智泉, 陈家乐, and 贾俊炜

Abstract

Copyright of Electric Power Automation Equipment / Dianli Zidonghua Shebei is the property of Electric Power Automation Equipment Press and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

2. Harmonic instability analysis of distributed power stations considering dq-axis coupling and line distribution parameters

Author

GONG Liwu, CHEN Chao, QIAN Guoliang, ZHANG Wei, XU Fangwei, CHEN Kai, and ZHENG Hongru

Subjects

distributed power station, harmonic instability, distribution parameters, dq-axis coupling, transcendent equation, padé approximation, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

To address the challenge of solving the zero-pole of transcendental equation for distributed power station with simultaneous consideration of two factors， i.e.， dq-axis coupling and line distribution parameter， an impedance model for distributed power station considering the two factors is established. This paper proposes a matrix-determinant zero-pole solution method for transcendental equation using Padé approximation and provides detailed steps for calculating the zero-pole distribution of the transfer function. Furthermore，it analyzes the impact of the two factors on harmonic instability analysis in the system under different scenarios. The research demonstrates that the proposed method can accurately analyze harmonic instability issues when these two factors are considered simultaneously. And ignoring one of the two factors may result in the misjudgment of stability， and considering the line distribution parameter is a necessary prerequisite for solving the amplification point of high-frequency harmonics. The effectiveness of the proposed method is verified by simulation.

Published

2024

3. 考虑 dq 轴耦合及线路分布参数的分布式电站谐波 不稳定分析.

Author

龚利武, 陈超, 钱国良, 张炜, 徐方维, 陈锴, and 郑鸿儒

Abstract

Copyright of Zhejiang Electric Power is the property of Zhejiang Electric Power Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

4. 基于超越方程极点分布间接判定的分布式电站 谐波不稳定分析方法.

Author

徐方维, 陈 锴, 郑鸿儒, 周 全, 陈 超, 龚利武, 张 炜, and 唐 昕

Abstract

Copyright of Electric Power Automation Equipment / Dianli Zidonghua Shebei is the property of Electric Power Automation Equipment Press and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

5. A harmonic instability analysis method for solving the zero and pole distributions of the transcendental equation

Author

XU Fangwei, CHEN Kai, ZHENG Hongru, CHEN Chao, MA Zhiquan, and LUO Zhongyou

Subjects

distributed parameters, transcendental equation, harmonic instability, zero and pole distributions, pade approximation, wind farm, Applications of electric power, TK4001-4102

Abstract

The distributed parameter model of the transmission line is a necessary premise for accurately analysing the harmonic instability of the wind farm. However, when the model is used for harmonic instability analysis, it causes difficulties in solving the zero and pole distributions of the transcendental equation of the system. Given this, the impedance model of the wind farm considering the line distribution parameters is established and verified. Next, a method based on Pade approximation to solve the zero and pole distributions of the transcendental equation is proposed. The exponential function is approximated to the rational fraction only by selecting the order of the rational fraction, without fitting coefficients. Further, the influence of different transmission line models on the harmonic instability under different line lengths and grid strengths is analyzed. Finally, the effectiveness of the proposed method is verified by the simulation case. The results show that the effect of distribution parameters cannot be ignored, otherwise, it may lead to the inaccurate analysis of stability and deviation or even omission of harmonic amplification points in the high-frequency band. The proposed method can not only accurately evaluate the stability of the system, but also analyze the harmonic amplification points.

Published

2023

6. 一种求解超越方程零极点分布的谐波不稳定分析方法.

Author

徐方维, 陈锴, 郑鸿儒, 陈超, 马智泉, and 罗忠游

Abstract

Copyright of Electric Power Engineering Technology is the property of Editorial Department of Electric Power Engineering Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

7. Online-Harmonic-Detection-Based System Stabilization Function for Grid-Forming Inverters Under Various Grid Conditions

Author

Le Kong, Yaosuo Xue, Liang Qiao, and Fei Gae Wang

Subjects

Grid-forming inverters, harmonic instability, online harmonic detection, passivity-based design, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

In power systems with grid-forming inverters (GFMs), small-signal instability issues could occur due to harmonic excitation, impedance interactions, and poor inverter control design. There mainly exist two types of stability issues based on the frequency range. One is the low-frequency resonance (0 – 2f0 Hz) and the other is the high-frequency harmonics (above 2f0 Hz), where f0 is the system fundamental frequency. By assuming that the low-frequency related controls are well designed, this paper addresses the high-frequency harmonic issues. The goal is to develop a system stabilization function (SSF) to eliminate any high-frequency stability issues under various grid conditions without affecting predefined low-frequency behaviors. The idea is to conduct the inverter passivation test at the system harmonic resonant frequency so that the corresponding harmonic instability can be removed. To achieve this, the resonant frequency of the harmonic instability is detected first, and then if the magnitude of the resonant component exceeds the threshold value, the proposed SSF will be enabled, thus the system would be stabilized. Both simulation and experimental tests are conducted to validate the effectiveness of the proposed approach.

Published

2023

8. Analysis of Harmonic Instability of Tokamak Power System Caused by Rectifier Transformer Bias

Author

Jiansheng WANG, Huafeng MAO, Zhiwei MAO, and Liuwei XU

Subjects

non characteristic subharmonic, tokamak power system, modulation function, dc bias, harmonic instability, Energy industries. Energy policy. Fuel trade, HD9502-9502.5

Abstract

[Introduction] The paper aims to effectively suppress the disturbance of non characteristic harmonics to the power grid in the tokamak power supply system, the paper studies the mechanism of low-frequency harmonics in the tokamak power supply system. [Method] By introducing an improved switching function model, selected ITER fusion device as an example and established its corresponding AC/DC equivalent circuit model combined with its corresponding parameters, the corresponding output second harmonic was obtained through calculation and simulation. [Result] The ratio of output to input is calculated, and the stability factor value almost tends to zero. [Conclusion] It is determined that the DC bias of rectifier transformer do not cause harmonic instability of the system.

Published

2022

9. Harmonic Instability of LCL -Type Grid-Connected Inverter Caused by the Pole-Zero Cancellation: A Case Study.

Author

Wang, Xuehua, He, Yuying, Pan, Donghua, Zhang, Hao, Ma, Yixiao, and Ruan, Xinbo

Subjects

*DRAWING techniques, *MICROGRIDS, *RESONANCE, *HARMONIC analysis (Mathematics)

Abstract

Pole-zero cancellation technique has drawn much attention to tackle the filter resonance of the LCL-type grid-connected inverter for simplifying the stability-oriented design. However, its potential stability risk was rarely concerned. As one representative of this technique, the weighted average current (WAC) control is assessed. It is found that the LCL resonance in the state variable WAC is cancelled out by pole-zero cancellation, but the ones in some uncontrollable or unobservable state variables such as the grid current are still inherited, resulting in harmonic instability. From this perspective, this article appeals that this technique should be cautiously used or even avoided. An extended WAC control which avoids pole-zero cancellation is proposed accordingly. The theoretical expectations are finally validated by simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2022

10. 整流变压器偏磁对托卡马克电源系统谐波不稳定的分析.

Author

王健声, 茆华风, 茆智伟, and 留伟

Abstract

Copyright of Southern Energy Construction is the property of Southern Energy Construction Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

11. Voltage-Source Converter Harmonic Characteristic Modeling Using Hammerstein–Wiener Approach.

Author

Abdelsamad, Ahmed S., Myrzik, Johanna M. A., Kaufhold, Elias, Meyer, Jan, and Schegner, Peter

Subjects

RENEWABLE energy sources, DISTRIBUTED power generation, POWER electronics, ELECTRIC potential, HARMONIC distortion (Physics), QUANTUM coherence

Abstract

Power electronic (PE) penetration in energy networks has been increasing rapidly in recent years due to the campaign to rely on distributed generation as a clean, sustainable energy source. This increase leads to new challenges and stability problems occurring because of the increase in the harmonic current injected into the power network. To study and address such issues, accurate and computationally efficient models are required. In this article, a Hammerstein–Wiener-based approach is proposed to develop black-box models for PE devices capable of capturing the devices’ harmonic characteristics. A novel method based on magnitude square coherence is also proposed to compare the results of different models in the frequency domain. The method is implemented in a simulation environment and was further tested and validated through laboratory measurements. [ABSTRACT FROM AUTHOR]

Published

2021

12. 计及变压器铁芯饱和的LCC-HVDC输电系统谐波不稳定性评估与应用.

Author

刘 对, 李晓华, 蔡泽祥, and 蔡苏斌

Abstract

Copyright of Electric Power Automation Equipment / Dianli Zidonghua Shebei is the property of Electric Power Automation Equipment Press and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2021

13. Automation of Impedance Measurement for Harmonic Stability Assessment of MMC-HVDC Systems.

Author

Dongsheng Yang, Xiongfei Wang, Ndreko, Mario, Winter, Wilhelm, Juhlin, Robert, and Krontiris, Athanasios

Subjects

HIGH-voltage direct current transmission, INDEPENDENT system operators, ELECTROMAGNETISM, ELECTRIC power transmission, AUTOMATION

Abstract

Modular Multilevel Converter-High-Voltage Direct Current (MMC-HVDC) transmission systems can interact with the grid impedance, leading to harmonic instability phenomena. To screen the risk of harmonic instability in multi-vendor MMCHVDC-based transmission systems, an automated impedance measurement toolbox is developed for Transmission System Operator (TSO), which allows the TSO to extract the harmonic impedance model directly from the vendor-specified black-box electromagnetic transient models of MMC-HVDC systems. The automated toolbox can be seamlessly incorporated with the PSCAD software environment, and it is benchmarked in two steps in this work: first for a generic MMC system against its analytically derived impedance, and then for a vendor-specific MMC installation against the model used by the vendor. Finally, the application of the toolbox for a generic HVDC system tested in a transmission power network is presented. [ABSTRACT FROM AUTHOR]

Published

2019

14. Harmonic Instability Analysis and Suppression Method Based on αβ- Frame Impedance for Trains and Network Interaction System.

Author

Tao, Haidong, Hu, Haitao, Zhu, Xiaojuan, Zhou, Yi, and He, Zhengyou

Subjects

*HARMONIC analysis (Mathematics), *GYROTRONS, *ELECTRIC impedance, *TRANSFER functions, *MODEL railroads

Abstract

The high-frequency negative damping characteristics of the electric train and the traction network interaction system may excite harmonic instability issues. This paper proposes a detailed impedance model and a simplified method in the αβ-frame for investigating the high-frequency impedance characteristic of the electric train. Meanwhile, the impedance model is validated by means of the frequency sweeping method. Based on the αβ-frame impedance model of the train, the negative damping range is mathematically expressed. It is helpful for analyzing the impacts of controller bandwidths and network impedances on the harmonic instability. In addition, a voltage feedforward filter combining its transfer function is proposed to enhance the system stability. Taking advantages of the proposed voltage feedforward filter, the output impedance of the train can maintain passive characteristics well in a specific high-frequency range, effectively avoiding harmonic instability issues. Simulation and experimental results validate the effectiveness of the proposed harmonic instability analysis and suppression methods. [ABSTRACT FROM AUTHOR]

Published

2019

15. Bus Participation Factor Analysis for Harmonic Instability in Power Electronics Based Power Systems.

Author

Ebrahimzadeh, Esmaeil, Blaabjerg, Frede, Wang, Xiongfei, and Bak, Claus Leth

Subjects

*HARMONIC distortion (Physics), *POWER electronics, *MIMO systems, *CASCADE converters, *ELECTRIC admittance

Abstract

Compared with the conventional power systems, large-scale power electronics based power systems present a more complex situation, where harmonic instability may be induced by the mutual interactions between the inner control loops of the converters. This paper presents an approach to locate which power converters and buses are more sensitive and have a significant contribution to the harmonic instability. In the approach, a power electronics based system is introduced as a multi-input multi-output (MIMO) dynamic system by means of a dynamic admittance matrix. Bus participation factors (PFs) are calculated by the oscillatory mode sensitivity analysis versus the elements of the MIMO transfer function matrix. The PF analysis detects which power electronic converters or buses have a higher participation in harmonic instability excitation than others or at which buses such instability problems have a higher impact. In order to confirm the effectiveness of the presented approach, time-domain simulation results are provided for a 400-MW wind farm in PSCAD software environment. [ABSTRACT FROM AUTHOR]

Published

2018

16. Impedance-Based Harmonic Instability Assessment in a Multiple Electric Trains and Traction Network Interaction System.

Author

Tao, Haidong, Hu, Haitao, Wang, Xiongfei, Blaabjerg, Frede, and He, Zhengyou

Subjects

*ELECTRIC impedance, *RAILROAD trains, *TRACTION (Engineering), *VEHICLES, *FRICTION

Abstract

This paper presents an impedance-based method to systematically investigate the interaction between multiple trains and a traction network, focusing on evaluating the harmonic instability problem. First, the interaction mechanism of the multitrain and the traction network is represented as a feedback interconnection of the two subsystems, i.e., an equivalent output impedance of the traction network and an equivalent input admittance of the multitrain. Then, the harmonic instability is evaluated through a series of pole-zero diagrams drawn from the closed-loop transfer matrix of the multitrain and network system. The interaction system is unstable, and the harmonic instability will happen if there are some high-frequency poles of the closed-loop system locating in the right-half plane. This method is used for analyzing the harmonic instability phenomena, the characteristics, influential factors, and potential mitigation schemes. The theoretical results are further validated by the simulations and experiments. [ABSTRACT FROM AUTHOR]

Published

2018

17. Train?Network Interactions and Stability Evaluation in High-Speed Railways?Part II: Influential Factors and Verifications.

Author

Hu, Haitao, Tao, Haidong, Wang, Xiongfei, Blaabjerg, Frede, He, Zhengyou, and Gao, Shibin

Subjects

*HIGH speed trains, *COMPUTER simulation, *ELECTRIC railroads, *ELECTRIC impedance, *HARMONIC analyzers, *AUTOTRANSFORMERS

Abstract

Low-frequency oscillation (LFO), harmonic resonance, and harmonic instability phenomena in high-speed railways (HSRs) result from the interactions between multiple electric trains and the traction network. A train–network interaction system and a unified impedance-based model are therefore presented to reveal the mechanism of these three phenomena in Part I of the two-part paper. Part II of the paper presents and compares the detailed simulation and experiment results to investigate the available possible influential factors, verifications, and discussions of the three phenomena. The influential factors include the following: 1) four-quadrant converter (4QC) parameters involving the control parameters of the current controller (CC), the voltage controller (VC), and the phase-locked loop (PLL); 2) network parameters involving the utility power system, traction transformer, primary/secondary supply lines, catenary lines, and autotransformers (ATs); and 3) different numbers and positions of trains and railway lines will also be considered and discussed. In order to validate the theoretical results, the time-domain simulation and experiment system have been conducted. Finally, the differences and the relations among the three phenomena are discussed. [ABSTRACT FROM AUTHOR]

Published

2018

18. Train?Network Interactions and Stability Evaluation in High-Speed Railways?Part I: Phenomena and Modeling.

Author

Hu, Haitao, Tao, Haidong, Blaabjerg, Frede, Wang, Xiongfei, He, Zhengyou, and Gao, Shibin

Subjects

*HIGH speed trains, *ELECTRIC impedance, *FREQUENCY-domain analysis, *ELECTRIC transformers, *ELECTRIC railroads

Abstract

This paper presents an impedance-based model to systematically investigate the interaction performance of multiple trains and traction network interaction system, aiming to evaluate the serious phenomena, including low-frequency oscillation (LFO), harmonic resonance, and harmonic instability. The train–network interaction mechanism is therefore studied, and one presents a detailed coupling model for investigating the three interactive phenomena and their characteristics, influential factors, analysis methods, and possible mitigation schemes. In Part I of the two-part paper, the measured waveforms of such three phenomena are first characterized to indicate their features and principles. A unified framework of the train–traction network system for investigating the three problems is then presented. In order to reveal the interaction mechanism, all-frequency impedance behaviors of the electric trains and traction network are equally modeled. In which, an impedance-based input behavior of the train is fully investigated with considering available controllers and their parameters in DQ-domain. The entire traction network, including traction transformer, catenary, supply lines, is represented in a frequency-domain nodal matrix. Furthermore, the impedance–frequency responses of both electric train and traction network are measured and validated through frequency scan method. Finally, a generalized train–network simulation and experimental system are conducted for verifying the theoretical results of the two-part paper. [ABSTRACT FROM AUTHOR]

Published

2018

19. Impedance Modeling and Stability Analysis of the Converters in a Double-Fed Induction Generator (DFIG)-Based System

Author

Xunjun Chen and Zhigang Liu

Subjects

DFIG, PWM converter, impedance modeling, harmonic instability, RTDS, Technology

Abstract

Harmonic stability of double-fed induction generators (DFIGs) now has become a significant topic because of its harmful impact on power quality issues of the system. Since the double pulse width modulation (PWM) converter is one of the main harmonic sources in DFIGs, it may cause harmonic instability with increasing harmonic contents. Thus, the modeling and stability analyses of PWM converters in DFIGs are essential steps to assess the harmonic stability of DFIGs. Aiming at dual PWM converters, which include the grid side converter (GSC) and the rotor side converter (RSC), this paper divides converters into two parts: circuit modules and control modules. Closed-loop input impedance models of each module are then derived by means of transfer functions. Hence, the stability of the system can be readily predicted through Nyquist diagrams. The contributions of parameters to the system’s harmonic stability are also identified. Finally, time-domain simulations are conducted in a real-time digital simulation (RTDS) system. Simulation results confirm that the established impedance model can effectively reveal the stability of the DFIG-based system and can give critical conditions for the occurrence of harmonic instability.

Published

2019

20. Frequency-Domain Modeling and Simulation of DC Power Electronic Systems Using Harmonic State Space Method.

Author

Kwon, JunBum, Wang, Xiongfei, Blaabjerg, Frede, and Bak, Claus Leth

Subjects

*DIRECT currents, *ELECTRIC vehicles, *SWITCHING circuits, *SIMULATION methods & models, *COMPUTER storage devices

Abstract

For the efficiency and simplicity of electric systems, the dc power electronic systems are widely used in a variety of applications such as electric vehicles, ships, and aircraft and in homes. In these systems, there could be a number of dynamic interactions and frequency coupling between network and loads and other converters. Hence, time-domain simulations are usually required to consider such a complex system behavior. However, simulations in the time domain may increase the calculation time and the utilization of computer memory. Furthermore, frequency coupling driven by multiple converters with different switching frequencies or harmonics from ac–dc converters makes that harmonics and frequency coupling are both problems of ac system and challenges of dc system. This paper presents the modeling and simulation methods of a large dc system by using the harmonic state space (HSS) modeling. Through this method, the required computation time and CPU memory can be reduced, where this faster simulation can be an advantage of a large network simulation. Besides, the achieved results show the same results as that of the nonlinear time-domain simulation. Furthermore, the HSS modeling can describe how the frequency components are coupled with each other through the different switching frequency of each converter. [ABSTRACT FROM PUBLISHER]

Published

2017

21. Harmonic Instability Assessment Using State-Space Modeling and Participation Analysis in Inverter-Fed Power Systems.

Author

Wang, Yanbo, Wang, Xiongfei, Blaabjerg, Frede, and Chen, Zhe

Subjects

*ELECTRICAL harmonics, *STATE-space methods, *ELECTRIC inverters, *VOLTAGE control, *TIME delay systems, *EIGENVALUE equations

Abstract

This paper presents a harmonic instability analysis method using state-space modeling and participation analysis in the inverter-fed ac power systems. A full-order state-space model for the droop-controlled distributed generation (DG) inverter is built first, including the time delay of the digital control system, inner current and voltage control loops, and outer droop-based power control loop. Based on the DG inverter model, an overall state-space model of a two-inverter-fed system is established. The eigenvalue-based stability analysis is then presented to assess the influence of controller parameters on the harmonic instability of the power system. Moreover, the harmonic-frequency oscillation modes are identified, where participation analysis is presented to evaluate the contributions of different states to these modes and to further reveal how the system gives rise to harmonic instability. Based on the participation analysis, a reduced-order model for harmonic instability analysis is also proposed. The experimental results are presented for validating the theoretical analyses. [ABSTRACT FROM PUBLISHER]

Published

2017

22. Integrated Full-Frequency Impedance Modeling and Stability Analysis of the Train-Network Power Supply System for High-Speed Railways

Author

Xinyu Zhang, Lei Wang, William Dunford, Jie Chen, and Zhigang Liu

Subjects

harmonic resonance, harmonic instability, low-frequency oscillation, full-frequency impedance modeling, train- network power supply system, Technology

Abstract

To investigate the harmonic resonance, harmonic instability and low-frequency oscillation phenomena in high-speed railways, this paper proposes a full-frequency impedance model of the train-traction network system (simplified as ‘train-network’) based on d-q coordinates system. Compared with traditional models which deal with only the grid-side converter, the proposed model also includes its load models—the inverter and the traction motor. It also reflects complete control scheme of grid-side converter, which makes it easier to analyze unstable phenomena mentioned above. Moreover, this paper improves the impedance modeling of the network by taking the network impedance and admittance into detailed consideration. In addition, based on the proposed train-network model, the 3D figure and zero-pole diagram are also presented for the analysis of the stability of the integral system. Simulation and experiment results verify the accuracy of the model.

Published

2018

23. Harmonic Instability Analysis of a Single-Phase Grid-Connected Converter Using a Harmonic State-Space Modeling Method.

Author

Kwon, Jun Bum, Wang, Xiongfei, Blaabjerg, Frede, Bak, Claus Leth, Wood, Alan R., and Watson, Neville R.

Subjects

*RENEWABLE energy sources, *CONVERTERS (Electronics), *ELECTRICAL harmonics, *ELECTRIC power conversion harmonics, *ELECTRIC power distribution grids

Abstract

The increasing number of renewable energy sources in the distribution grid is becoming a major issue for utility companies since grid-connected converters are operating at different operating points due to the probabilistic characteristics of the renewable energy. Usually, the harmonics and impedance from other renewable energy sources are not taken carefully into account in the installation and design of the systems. It can bring an unknown harmonic instability into a multiple power-sourced system and makes the analysis difficult due to the complexity of the grid network. This paper proposes a new model of a single-phase grid-connected renewable energy source by using the harmonic state-space modeling approach, which can identify such problems. The model can be extended to a multiple connected converter analysis. The modeling results show the harmonic impedance matrixes, which represent the harmonic coupling characteristic, as well as different dynamic characteristics. The theoretical modeling and analysis are verified by simulations, as well as experimental results. [ABSTRACT FROM PUBLISHER]

Published

2016

24. Harmonic Instability in MMC-HVDC Converters Resulting From Internal Dynamics.

Author

Li, Tan, Gole, Aniruddha M., and Zhao, Chengyong

Subjects

*FREQUENCY changers, *ELECTRIC current converters, *PHASOR measurement, *ELECTRIC controllers, *ELECTRICAL harmonics

Abstract

This paper reveals the existence of poorly damped resonant modes in the modular multilevel converter (MMC) that can result in harmonic instability. A small-signal model based on dynamic phasors is introduced which takes into consideration the dynamics of internal variables, such as circulating arm currents, which have a tendency for a large second harmonic component and module capacitor voltage ripple, which has other harmonic components. The small-signal model is validated by comparison with the electromagnetic transient simulation of a detailed model. It is shown that the use of an active circulating current suppressing scheme can effectively improve the damping of internal harmonic modes in comparison with a passive filter used for the same purpose. The damping of internal harmonic modes has been shown to be significantly impacted by the gains of the MMC's outer-loop controller but is less sensitive to the ac system strength or the gain of the phase-locked loop. A larger arm resistance also increases the damping of these internal modes. [ABSTRACT FROM PUBLISHER]

Published

2016

25. Multi-Frequency State-Space Model of MMC-HVDC System for Design-Oriented Stability Analysis

Author

Wilhelm Winter, Dongsheng Yang, Xiongfei Wang, Mario Ndreko, EIRES System Integration, Cyber-Physical Systems Center Eindhoven, Electrical Energy Systems, Center for Care & Cure Technology Eindhoven, and Power Conversion

Subjects

frequency coupling, State-space representation, state-space model, business.industry, Computer science, Automatic frequency control, Transmission system, Modular design, Stability (probability), Power (physics), Control theory, Computer Science::Systems and Control, Control system, Sensitivity (control systems), business, harmonic instability, MMC-HVDC

Abstract

The frequency-coupling dynamics of the modular multilevel converter (MMC) complicate the stability analysis and controller design of MMC-based high-voltage direct current (HVDC) transmission systems. In this paper, a multi-frequency state-space model of MMC with the closed-loop control system is established, which allows to identify the critical oscillation modes and their sensitivities to the control parameters, and thus provides a design-oriented stability analysis. The mathematical relationships between the multi-frequency state-space models in different frames are established, which bridges the gap between the frequency-coupling dynamics of the MMC power stage and that of asymmetrical control loops. Design-oriented stability analysis is then performed based on a generic MMC-HVDC model, which confirms the effectiveness of the modeling techniques.

Published

2020

26. Impedance Modeling and Stability Analysis of Grid-Interactive Converters

Author

Liao, Yicheng

Subjects

grid interaction, grid-forming, impedance stability, right half plane pole, passivity, frequency domain, converter, harmonic instability, sideband oscillation

Published

2020

27. Impedance-Based Harmonic Instability Assessment in a Multiple Electric Trains and Traction Network Interaction System

Author

Zhengyou He, Xiongfei Wang, Haidong Tao, Haitao Hu, and Frede Blaabjerg

Subjects

Interconnection, Computer science, Multitrain and network interaction, 020209 energy, 020208 electrical & electronic engineering, Traction (engineering), 02 engineering and technology, Transfer matrix, Instability, Industrial and Manufacturing Engineering, Harmonic analysis, Impedance-based analysis, Electrified railways, Control and Systems Engineering, Control theory, Harmonic instability, 0202 electrical engineering, electronic engineering, information engineering, Output impedance, Electrical and Electronic Engineering, Equivalent input, Electrical impedance

Abstract

This paper presents an impedance-based method to systematically investigate the interaction between multi-train and traction networks, focusing on evaluating the harmonic instability problems. Firstly, the interaction mechanism of multi-train and the traction network is represented as a feedback interconnection of the two subsystems, i.e., an equivalent output impedance of the traction network and an equivalent input admittance of the multi-train. Then the harmonic instability is evaluated through a series of pole-zero diagrams drawn from the closed loop transfer matrix of the multi-train and traction network interaction system. The interaction system is unstable and the harmonic instability will happen if there are some high frequency poles of the closed loop system located in the right half plane. This method is used for analyzing the harmonic instability phenomena and its characteristics, its factors and also possible mitigation schemes. The theoretical results are further validated by the simulations and experiments.

Published

2018

28. Train–Network Interactions and Stability Evaluation in High-Speed Railways—Part II: Influential Factors and Verifications

Author

Zhengyou He, Haitao Hu, Frede Blaabjerg, Haidong Tao, Xiongfei Wang, and Shibin Gao

Subjects

Computer science, Oscillation, 020209 energy, medicine.medical_treatment, Train-network interactions, 020208 electrical & electronic engineering, Impedance- based model, 02 engineering and technology, Traction (orthopedics), Low-frequency oscillation, Electric power system, Harmonic resonance, Voltage controller, Control theory, Harmonic instability, 0202 electrical engineering, electronic engineering, information engineering, Harmonic, Autotransformer, medicine, Electrical and Electronic Engineering, Electrical impedance

Abstract

Low-frequency oscillation (LFO), harmonic resonance, and harmonic instability phenomena in high-speed railways (HSRs) result from the interactions between multiple electric trains and the traction network. A train-network interaction system and a unified impedance-based model are therefore presented to reveal the mechanism of these three phenomena in Part I of the two-part paper. Part II of the paper presents and compares the detailed simulation and experiment results to investigate the available possible influential factors, verifications, and discussions of the three phenomena. The influential factors include the following: 1) four-quadrant converter (4QC) parameters involving the control parameters of the current controller (CC), the voltage controller (VC), and the phase-locked loop (PLL); 2) network parameters involving the utility power system, traction transformer, primary/secondary supply lines, catenary lines, and autotransformers (ATs); and 3) different numbers and positions of trains and railway lines will also be considered and discussed. In order to validate the theoretical results, the time-domain simulation and experiment system have been conducted. Finally, the differences and the relations among the three phenomena are discussed.

Published

2018

29. Train–Network Interactions and Stability Evaluation in High-Speed Railways–Part I: Phenomena and Modeling

Author

Haidong Tao, Shibin Gao, Frede Blaabjerg, Zhengyou He, Xiongfei Wang, and Haitao Hu

Subjects

Computer science, 020209 energy, medicine.medical_treatment, Train-network interactions, 020208 electrical & electronic engineering, Traction (engineering), 02 engineering and technology, Traction (orthopedics), High-speed railway, Low-frequency oscillation, Instability, Harmonic resonance, Control theory, Harmonic instability, 0202 electrical engineering, electronic engineering, information engineering, medicine, Electrical and Electronic Engineering, Electrical impedance

Abstract

This paper presents an impedance-based model to systematically investigate the interaction performance of multiple trains and traction network interaction system, aiming to evaluate the serious phenomena, including low-frequency oscillation (LFO), harmonic resonance, and harmonic instability. The train-network interaction mechanism is therefore studied, and one presents a detailed coupling model for investigating the three interactive phenomena and their characteristics, influential factors, analysis methods, and possible mitigation schemes. In Part I of the two-part paper, the measured waveforms of such three phenomena are first characterized to indicate their features and principles. A unified framework of the train-traction network system for investigating the three problems is then presented. In order to reveal the interaction mechanism, all-frequency impedance behaviors of the electric trains and traction network are equally modeled. In which, an impedance-based input behavior of the train is fully investigated with considering available controllers and their parameters in DQ-domain. The entire traction network, including traction transformer, catenary, supply lines, is represented in a frequency-domain nodal matrix. Furthermore, the impedance-frequency responses of both electric train and traction network are measured and validated through frequency scan method. Finally, a generalized train-network simulation and experimental system are conducted for verifying the theoretical results of the two-part paper.

Published

2018

30. Nonzero Bound on Fiedler Eigenvalue Causes Exponential Growth of H-Infinity Norm of Vehicular Platoon.

Author

Herman, Ivo, Martinec, Dan, Hurak, Zdenek, and Sebek, Michael

Subjects

*MOTOR vehicles, *EIGENVALUES, *LAPLACIAN matrices, *TRANSFER functions, *SPACE

Abstract

We consider platoons composed of identical vehicles and controlled in a distributed way, that is, each vehicle has its own onboard controller. The regulation errors in spacing to the immediately precedeing and following vehicles are weighted differently by the onboard controller, which thus implements an asymmetric bidirectional control scheme. The weights can vary along the platoon. We prove that such platoons have a nonzero uniform bound on the second smallest eigenvalue of the graph Laplacian matrix—the Fiedler eigenvalue. Furthermore, it is shown that existence of this bound always signals undesirable scaling properties of the platoon. Namely, the H-infinity norm of the transfer function of the platoon grows exponentially with the number of vehicles regardless of the controllers used. Hence the benefits of a uniform gap in the spectrum of a Laplacian with an asymetric distributed controller are paid for by poor scaling as the number of vehicles grows. [ABSTRACT FROM PUBLISHER]

Published

2015

31. Harmonic Instability Assessment Using State-Space Modeling and Participation Analysis in Inverter-Fed Power Systems

Author

Frede Blaabjerg, Yanbo Wang, Zhe Chen, and Xiongfei Wang

Subjects

Engineering, business.industry, 020209 energy, Eigenvalue, 020208 electrical & electronic engineering, State-space model, 02 engineering and technology, Harmonic analysis, Electric power system, Inverter-fed power system, Control and Systems Engineering, Control theory, Harmonics, Harmonic instability, 0202 electrical engineering, electronic engineering, information engineering, Harmonic, Inverter, Voltage droop, Electrical and Electronic Engineering, business, Time delay, Power control

Abstract

This paper presents a harmonic instability analysis method using state-space modeling and participation analysis in the inverter-fed ac power systems. A full-order state-space model for the droop-controlled Distributed Generation (DG) inverter is built first, including the time delay of the digital control system, inner current and voltage control loops, and outer droop-based power control loop. Based on the DG inverter model, an overall state-space model of a two-inverter-fed system is established. The eigenvalue-based stability analysis is then presented to assess the influence of controller parameters on the harmonic instability of the power system. Moreover, the harmonic-frequency oscillation modes are identified, where participation analysis is presented to evaluate the contributions of different states to these modes and to further reveal how the system gives rise to harmonic instability. Based on the participation analysis, a reduced-order model for harmonic instability analysis is also proposed. The experimental results are presented for validating the theoretical analyses.

Published

2017

32. Bus Participation Factor Analysis for Harmonic Instability in Power Electronics Based Power Systems

Author

Xiongfei Wang, Claus Leth Bak, Esmaeil Ebrahimzadeh, and Frede Blaabjerg

Subjects

power electronic based systems, Admittance, Computer science, 020209 energy, 02 engineering and technology, Power (physics), Admittance parameters, Harmonic analysis, Electric power system, sensitivity analysis, Power electronics, Harmonic instability, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Harmonic, participation factor (PF) analysis, Electrical and Electronic Engineering, Excitation

Abstract

Compared with the conventional power systems, large-scale power electronics based power systems present a more complex situation, where harmonic instability may be induced by the mutual interactions between the inner control loops of the converters. This paper presents an approach to locate which power converters and buses are more sensitive and have a significant contribution to the harmonic instability. In the approach, a power electronics based system is introduced as a multi-input multi-output (MIMO) dynamic system by means of a dynamic admittance matrix. Bus participation factors (PFs) are calculated by the oscillatory mode sensitivity analysis versus the elements of the MIMO transfer function matrix. The PF analysis detects which power electronic converters or buses have a higher participation in harmonic instability excitation than others or at which buses such instability problems have a higher impact. In order to confirm the effectiveness of the presented approach, time-domain simulation results are provided for a 400-MW wind farm in PSCAD software environment.

Published

2018

33. The Effect of SVC's Elements and Power System's Parameters on Harmonic Magnification: An Experimental Study.

Author

Abdulla, Mohamed and Salameh, Ziyad

Subjects

*EQUALIZERS (Electronics), *VOLTAGE regulators

Abstract

Static var compensator (SVC) is used to maintain constant load voltage by compensating the var required by poor power factor loads. The SVC is also used to balance the unbalanced three phase loads. The side effect of the SVC is the generation of harmonic components. Under certain conditions, one of the harmonic components generated by the SVC becomes magnified. This magnified harmonic component leads to a time-bifurcation instability in the thyristor controlled reactors (TCR). This paper shows the effect of the SVCs inductor on harmonic magnification and the time-bifurcation. The experimental results are reported, and the time-bifurcation of the TCR current is generated. [ABSTRACT FROM AUTHOR]

Published

1999

34. Frequency Domain Modeling and Simulation of DC Power Electronic Systems Using Harmonic State Space Method

Author

JunBum Kwon, Claus Leth Bak, Xiongfei Wang, and Frede Blaabjerg

Subjects

Engineering, business.industry, 020209 energy, 020208 electrical & electronic engineering, 02 engineering and technology, Converters, Network simulation, Modeling and simulation, DC distribution network, Frequency domain, Harmonics, Harmonic State Space Modeling, Harmonic instability, 0202 electrical engineering, electronic engineering, information engineering, Harmonic, Electronic engineering, Time domain, Electrical and Electronic Engineering, business, DC bias

Abstract

For the efficiency and simplicity of electric systems, the dc power electronic systems are widely used in a variety of applications such as electric vehicles, ships, aircraft and also in homes. In these systems, there could be a number of dynamic interactions and frequency coupling between network and loads and other converters. Hence, time-domain simulations are usually required to consider such a complex system behavior. However, simulations in the time-domain may increase the calculation time and the utilization of computer memory. Furthermore, frequency coupling driven by multiple converters with different switching frequency or harmonics from ac-dc converters makes that harmonics and frequency coupling are both problems of ac system and challenges of dc system. This paper presents a modeling and simulation method for a large dc power electronic system by using Harmonic State Space (HSS) modeling. Through this method, the required computation time and CPU memory can be reduced, where this faster simulation can be an advantage of a large network simulation. Besides, the achieved results show the same results as the non-linear time-domain simulation. Furthermore, the HSS modeling can describe how the frequency components are coupled with each other through the different switching frequency of each converter.

Published

2017

35. Harmonic Instability Analysis of a Single-Phase Grid-Connected Converter Using a Harmonic State-Space Modeling Method

Author

Claus Leth Bak, Neville R. Watson, Alan R. Wood, Frede Blaabjerg, JunBum Kwon, and Xiongfei Wang

Subjects

Engineering, Grid network, business.industry, 020209 energy, 020208 electrical & electronic engineering, Probabilistic logic, 02 engineering and technology, Converters, 7. Clean energy, Industrial and Manufacturing Engineering, Renewable energy, Harmonic analysis, Single Phase Grid connected converter, Control and Systems Engineering, Harmonics, Harmonic State Space Modeling, Harmonic instability, 0202 electrical engineering, electronic engineering, information engineering, Harmonic, Electronic engineering, State space, Electrical and Electronic Engineering, business

Abstract

The increasing number of renewable energy sources in the distribution grid is becoming a major issue for utility companies since grid-connected converters are operating at different operating points due to the probabilistic characteristics of the renewable energy. Usually, the harmonics and impedance from other renewable energy sources are not taken carefully into account in the installation and design of the systems. It can bring an unknown harmonic instability into a multiple power-sourced system and makes the analysis difficult due to the complexity of the grid network. This paper proposes a new model of a single-phase grid-connected renewable energy source by using the harmonic state-space modeling approach, which can identify such problems. The model can be extended to a multiple connected converter analysis. The modeling results show the harmonic impedance matrixes, which represent the harmonic coupling characteristic, as well as different dynamic characteristics. The theoretical modeling and analysis are verified by simulations, as well as experimental results.

Published

2016

36. Admittance Modeling of Voltage and Current Controlled Inverter for Harmonic Instability Studies

Author

Bakhtyar Hoseinzadeh and Claus Leth Bak

Subjects

Engineering, Wind power, Admittance, business.industry, 020209 energy, Current-controlled inverter, 020208 electrical & electronic engineering, 02 engineering and technology, Impedance-based analysis, Control theory, Power electronics, Frequency domain, Harmonic instability, 0202 electrical engineering, electronic engineering, information engineering, Harmonic, Inverter, Voltage-controlled inverter, business, Electrical impedance, Voltage

Abstract

This paper proposes an impedance/admittance-based model for voltage and current controlled inverters with passive elements suitable for harmonic instability study of grid connected inverters in frequency domain. This linearized model of inverters, significantly simplifies investigation of resonance instability and control loop interaction of wind turbines with each other and/or with the grid, while they are installed in wind farms. The derived impedance ratio at point of common connection demonstrates how the inverters participate in harmonic stability of the grid.

Published

2016

37. Integrated Full-Frequency Impedance Modeling and Stability Analysis of the Train-Network Power Supply System for High-Speed Railways

Author

Zhigang Liu, Jie Chen, Xinyu Zhang, William G. Dunford, and Lei Wang

Subjects

Control and Optimization, Admittance, Computer science, 020209 energy, Energy Engineering and Power Technology, 02 engineering and technology, lcsh:Technology, Traction motor, low-frequency oscillation, Control theory, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, harmonic instability, Engineering (miscellaneous), Electrical impedance, lcsh:T, Renewable Energy, Sustainability and the Environment, Oscillation, 020208 electrical & electronic engineering, Physics::Classical Physics, Power (physics), harmonic resonance, Harmonic, Inverter, full-frequency impedance modeling, Low-frequency oscillation, train- network power supply system, Energy (miscellaneous)

Abstract

To investigate the harmonic resonance, harmonic instability and low-frequency oscillation phenomena in high-speed railways, this paper proposes a full-frequency impedance model of the train-traction network system (simplified as &lsquo, train-network&rsquo, ) based on d-q coordinates system. Compared with traditional models which deal with only the grid-side converter, the proposed model also includes its load models&mdash, the inverter and the traction motor. It also reflects complete control scheme of grid-side converter, which makes it easier to analyze unstable phenomena mentioned above. Moreover, this paper improves the impedance modeling of the network by taking the network impedance and admittance into detailed consideration. In addition, based on the proposed train-network model, the 3D figure and zero-pole diagram are also presented for the analysis of the stability of the integral system. Simulation and experiment results verify the accuracy of the model.

Published

2018

38. Impedance Modeling and Stability Analysis of the Converters in a Double-Fed Induction Generator (DFIG)-Based System.

Author

Chen, Xunjun and Liu, Zhigang

Subjects

*INDUCTION generators, *NYQUIST diagram, *DIGITAL computer simulation, *PULSE width modulation, *TRANSFER functions

Abstract

Harmonic stability of double-fed induction generators (DFIGs) now has become a significant topic because of its harmful impact on power quality issues of the system. Since the double pulse width modulation (PWM) converter is one of the main harmonic sources in DFIGs, it may cause harmonic instability with increasing harmonic contents. Thus, the modeling and stability analyses of PWM converters in DFIGs are essential steps to assess the harmonic stability of DFIGs. Aiming at dual PWM converters, which include the grid side converter (GSC) and the rotor side converter (RSC), this paper divides converters into two parts: circuit modules and control modules. Closed-loop input impedance models of each module are then derived by means of transfer functions. Hence, the stability of the system can be readily predicted through Nyquist diagrams. The contributions of parameters to the system's harmonic stability are also identified. Finally, time-domain simulations are conducted in a real-time digital simulation (RTDS) system. Simulation results confirm that the established impedance model can effectively reveal the stability of the DFIG-based system and can give critical conditions for the occurrence of harmonic instability. [ABSTRACT FROM AUTHOR]

Published

2019

39. Analysis of harmonic coupling and stability in back-to-back converter systems for wind turbines using Harmonic State Space (HSS)

Author

Frede Blaabjerg, JunBum Kwon, Xiongfei Wang, and Claus Leth Bak

Subjects

Engineering, Operating point, Total harmonic distortion, Wind power, business.industry, Turbine, Harmonic analysis, Harmonic spectrum, Control theory, Harmonic State Space Modeling, Harmonic instability, Electronic engineering, Harmonic, Back-to-Back Converter, State space, business, Harmonics coupling, Wind-turbine

Abstract

Understanding about harmonic propagation in wind turbine converter is fundamental to research the influence of these on a large network harmonic distortion. Therefore, the analysis of wind turbine converter harmonic spectrum as well as the influence of converter operating point into the network is urgently important issues in harmonic studies on wind farm. However, the conventional modeling procedure and simplified model for controller design are not enough to analyze such complicated systems. Besides, they have many limitations in terms of including a non-linear component, different operating points and harmonic coupling analysis. Hence, it is critically needed to develop the advanced converter model, which can include almost all the possibilities. This paper develops the advanced Back to Back (BtB) converter model for wind farm application by means of Harmonic State Space (HSS) modeling method. The modeling and analysis results are remarkable that this model can include non-linear component and also show different operating points and harmonic coupling point, where this means each wind power converter can show the different impedance characteristics. The developed model can easily connected into the large wind farm model to analyze the overall steady-state harmonic as well as harmonic stability. All theoretical modeling and analysis is verified by means of simulation and experimental results.

Published

2015

40. The modeling and harmonic coupling analysis of multiple-parallel connected inverter using Harmonic State Space (HSS)

Author

Claus Leth Bak, JunBum Kwon, Xiongfei Wang, and Frede Blaabjerg

Subjects

Power converters, Multi-parallel connected inverter, Renewable energies, Transfer function, Power (physics), LTI system theory, Harmonic analysis, Control theory, Harmonics, Power electronics, Harmonic State Space Modeling, Harmonic instability, Harmonic, State space, Mathematics

Abstract

As the number of power electronics based systems are increasing, studies about overall stability and harmonic problems are rising. In order to analyze harmonics and stability, most research is using an analysis method, which is based on the Linear Time Invariant (LTI) approach. However, this can be difficult in terms of complex multi-parallel connected systems, especially in the case of renewable energy, where possibilities for intermittent operation due to the weather conditions exist. Hence, it can bring many different operating points to the power converter, and the impedance characteristics can change compared to the conventional operation. In this paper, a Harmonic State Space modeling method, which is based on the Linear Time varying theory, is used to analyze different operating points of the parallel connected converters. The analyzed results show that the HSS modeling approach explicitly can demonstrate other phenomenon, which can not be found in the conventional LTI approach. The theoretical modeling and analysis are verified by means of simulations and experiments.

Published

2015

41. Modeling and Simulation of DC Power Electronics Systems Using Harmonic State Space (HSS) Method

Author

Claus Leth Bak, Frede Blaabjerg, Xiongfei Wang, and JunBum Kwon

Subjects

Engineering, business.industry, Power (physics), Modeling and simulation, DC distribution network, Power electronics, Harmonic State Space Modeling, Harmonic instability, Harmonic, Electronic engineering, State space, Time domain, business, Computer memory, DC bias

Abstract

For the efficiency and simplicity of electric systems, the dc based power electronics systems are widely used in variety applications such as electric vehicles, ships, aircrafts and also in homes. In these systems, there could be a number of dynamic interactions between loads and other dc-dc converters. Hence, in order to analyze these problems, simulations are required to consider such a complex system, which typically are time consuming. However, simulations in the time domain may increase the calculation time and computer memory. Even though several simplified approaches may be developed based on the state-space averaging and generalized averaging, these also have limitations to show the same results as with the non-linear time domain simulations. This paper presents a modeling and simulation method for a large dc power electronic system by using Harmonic State Space (HSS) modeling. Through this method, the required computation time and CPU memory for large dc power electronics systems can be reduced. Besides, the achieved results show the same results as with the non-linear time domain simulation, but with the faster simulation time which is beneficial in a large network.

Published

2015

42. Precise model analysis for 3-phase high power converter using the Harmonic State Space modeling

Author

Xiongfei Wang, JunBum Kwon, Frede Blaabjerg, and Claus Leth Bak

Subjects

Harmonic transfer function, Total harmonic distortion, Harmonic interaction, Transfer function, Harmonic analysis, Harmonic balance, Control theory, Harmonics, Harmonic instability, Harmonic state space modeling, Time domain, Voltage source, Pulse-width modulation, Mathematics

Abstract

This paper presents about the generalized multi-frequency modeling and analysis methodology, which can be used in control loop design and stability analysis. In terms of the switching frequency of high power converter, there can be harmonics interruption if the voltage source converter has a low switching frequency ratio or multi-sampling frequency. The range of the control bandwidth can include the switching component. Thus, the systems become unstable. This paper applies the Harmonic State Space (HSS) Modeling method in order to find out the transfer function for each harmonics terms. The modeling procedure shows the precision in the analysis of the stability as well as the controller design. The overall results are validated by using not only the non-linear time domain simulation, but also the analytical model.

Published

2015

43. Integrated Full-Frequency Impedance Modeling and Stability Analysis of the Train-Network Power Supply System for High-Speed Railways.

Author

Zhang, Xinyu, Wang, Lei, Dunford, William, Chen, Jie, and Liu, Zhigang

Subjects

*HIGH speed trains, *ELECTRIC impedance, *CASCADE converters, *TRACTION motors, *ELECTRIC power distribution grids

Abstract

To investigate the harmonic resonance, harmonic instability and low-frequency oscillation phenomena in high-speed railways, this paper proposes a full-frequency impedance model of the train-traction network system (simplified as ‘train-network’) based on d-q coordinates system. Compared with traditional models which deal with only the grid-side converter, the proposed model also includes its load models—the inverter and the traction motor. It also reflects complete control scheme of grid-side converter, which makes it easier to analyze unstable phenomena mentioned above. Moreover, this paper improves the impedance modeling of the network by taking the network impedance and admittance into detailed consideration. In addition, based on the proposed train-network model, the 3D figure and zero-pole diagram are also presented for the analysis of the stability of the integral system. Simulation and experiment results verify the accuracy of the model. [ABSTRACT FROM AUTHOR]

Published

2018