&nbsp;多端口机电-电磁暂态混合仿真端口解耦指标研究

杨洋; 肖湘宁; 陶顺; 孙静

doi:10.3969/j.issn.1000－7229.2017.04.012

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电力建设 ›› 2017, Vol. 38 ›› Issue (4) : 86. DOI: 10.3969/j.issn.1000－7229.2017.04.012

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多端口机电-电磁暂态混合仿真端口解耦指标研究

杨洋1, 肖湘宁1, 陶顺1，孙静2

作者信息 +

Port Decoupling Index of Multi-Port Electromechanical and Electromagnetic Transient Hybrid Simulation

YANG Yang1, XIAO Xiangning1,TAO Shun1, SUN Jing2

Author information +

文章历史 +

摘要

摘要：首先分析了多端口耦合给机电-电磁暂态混合仿真造成的误差机理，推导了不考虑直流电流变化及考虑直流电流变化情况下端口之间的耦合关系。然后，为减小多端口建模引入的仿真误差，并在满足RTDS建模约束下尽可能地保证电磁侧的仿真精度，针对机电-电磁暂态混合仿真电磁侧建模进行了多端口解耦指标的研究。分别对不同耦合强度的端口解耦，采用FSV（feature selected validation）方法分析了端口耦合强度和仿真精度之间的定量关系，得到了满足FSV定性评估为“好”及以上的端口解耦指标。最后在基于某地区500 kV及以上电压等级复杂交直流电网建立的实时混合仿真平台上验证了所提解耦指标的有效性。

Abstract

ABSTRACT： This paper firstly analyzes the error mechanism of electromechanical and electromagnetic hybrid simulation caused by the multi-port coupling, and deduces the coupling relationship between ports with and without the change of DC current considered. Then, to reduce the simulation error caused by coupled multi-port modeling and ensure the simulation accuracy within the limitation of modeling ability of RTDS as much as possible, this paper studies the multi-port decoupling index for the electromagnetic side in electromechanical and electromagnetic transient hybrid simulation. According to port decoupling with different coupling strengths, this paper adopts feature selected validation （FSV） method to analyze the quantitative relationship between port coupling strength and simulation precision, and obtains the decoupling index of ports which fulfills the ‘good’ standard validated by FSV. Finally, the validity of the proposed decoupling index is validated through the real time hybrid simulation platform of complex 500 kV and above AC/DC power network in a certain area.

导出引用

杨洋, 肖湘宁, 陶顺，孙静. 多端口机电-电磁暂态混合仿真端口解耦指标研究[J]. 电力建设. 2017, 38(4): 86 https://doi.org/10.3969/j.issn.1000－7229.2017.04.012

YANG Yang, XIAO Xiangning,TAO Shun, SUN Jing. Port Decoupling Index of Multi-Port Electromechanical and Electromagnetic Transient Hybrid Simulation[J]. Electric Power Construction. 2017, 38(4): 86 https://doi.org/10.3969/j.issn.1000－7229.2017.04.012

中图分类号： TM 743

参考文献

［1］ HEFFERNAN M D, TURNER K S, ARRILLAGA J, et al. Computation of AC - DC system disturbances. Part I. Interactive coordination of generator and convertor transient models［J］. IEEE Transactions on Power Apparatus & Systems, 1981, PER-1（11）:4341-4348.

［2］REEVE J， ADAPA R. A new approach to dynamic analysis of AC networks incorporating detailed modeling of DC systems. Part II. principles and implementation［J］. IEEE Transactions on Power Delivery，1988, 3（4）: 2005-2011.

［3］ ANDERSON G W J, WATSON N R, ARNOLD C P, et al. A new hybrid algorithm for analysis of HVDC and FACTS systems［C］// Energy Management and Power Delivery，1995 International Conference on. IEEE, 1995:462-467.

［4］郑三立，韩英铎，雷宪章，等. NETOMAC在电力系统实时仿真中的应用［J］. 电网技术. 2003,27（1）: 18-21.

ZHENG Sanli，HAN Yingduo，LEI Xianzhang， et al. Application of NETOMAC in real-time simulation of power systems［J］. Power System Technology，2003，27（1）:18-21.

［5］ SU H, CHAN K W, SNIDER L A, et al. A parallel implementation of electromagnetic electromechanical hybrid simulation protocol［C］// IEEE International Conference on Electric Utility Deregulation, Restructuring and Power Technologies. IEEE, 2004:151-155.

［6］张树卿，梁旭，童陆园，等. 电力系统电磁/机电暂态实时混合仿真的关键技术［J］. 电力系统自动化, 2008,32（15）: 89-96.

ZHANG Shuqing，LIANG Xu，TONG Luyuan, et al. Key technologies of the power system electromagnetic/ electromechanical real time hybrid simulation［J］. Automation of Electric Power Systems，2008，27（15）:89-96.

［7］杨洋，肖湘宁，陶顺，等. 混合仿真电磁侧功率源等效误差原理分析及改进［J］. 电力系统自动化, 2015, 39（24）: 104-109.

YANG Yang， XIAO Xiangning，TAO Shun， et al. Electromagnetic side power source equivalent error principle analysis and its improvement for hybrid simulation［J］. Automation of electric power systems, 2015， 39（24）: 104-109.

［8］肖湘宁, 杨洋, 陶顺，等. 混合仿真电流源等值误差机理分析及改进［J］. 电力建设, 2016, 37（6）:38-42.

XIAO Xiangning，YANG Yang，TAO Shun， et al.Current source equivalent error mechanism analysis and its improvement for hybrid simulation［J］.Electric Power Construction， 2016， 37（6）:38-42.

［9］杨洋, 肖湘宁, 陶顺，等. 考虑衰减直流分量的dq－120改进算法及其在混合仿真中的应用［J］.电力建设, 2016,（06）:43-48.

YANG Yang, XIAO Xiangning, TAO Shun， et al.An improved dq－120 algorithm considering decaying DC component and its application in hybrid simulation［J］.Electric Power Construction，2016， 37（6）:43-48.

［10］张伯明，陈寿孙，严正. 高等电力网络分析（第2版）［M］. 北京：清华大学出版社, 2007.

［11］浙江大学直流输电科研组. 直流输电［M］. 北京: 电力工业出版社, 1982.

［12］RAHIMI E, GOLE A, DAVIES B, et al. Commutation failure analysis in multi-infeed HVDC systems［J］. IEEE Transactions on Power Delivery, 2011, 26（1）: 378-384.

［13］林伟芳，汤涌，卜广全. 多馈入交直流系统短路比的定义和应用［J］. 中国电机工程学报， 2008, 28（31）: 1-8.

LIN Weifang, TANG Yong, BU Guangquan. Definition and application of short circuit ratio for multi-infeed AC/DC power systems［J］.Proceedings of the CSEE， 2008, 28（31）: 1-8.

［14］金小明，周保荣，管霖，等. 多馈入直流交互影响强度的评估指标［J］. 电力系统自动化, 2009, 33（15）: 98-102.

JIN Xiaoming, ZHOU Baorong , GUAN Lin， et al.HVDC interaction strength-index for the Multi infeed-HVDC Power System［J］. Automation of Electric Power Systems, 2009, 33（15）: 98-102.

［15］张进. 电力系统动态仿真可信度研究［D］. 北京：华北电力大学, 2005.

ZHANG Jin. Research on validation of power system dynamic simulation［D］. Beijing： North China Electric Power University,2005.