线路纵联差动保护研究
|
摘要
电流差动保护是高压线路保护的一个重要发展方向。文章概述了差动保护的基本原理,并在此基础上对常规差动和变化量差动,零序差动,及线路的电容电流补偿做了深入研究,创新性的提出了零序辅助选相和T接线电容电流补偿两种新方法。本文在第四和第五章分析后可以发现变化量差动与常规差动相比,可以不受负荷电流影响,具有更高的灵敏度,而零序差动可以不受过渡电阻影响,快速切断故障,并且提出了零序辅助选相法。在文章的最后一章,研究了双端线,单端线及T接线的稳态和暂态电容电流补偿,采用本文的电容电流补偿方法,能大大降低区外故障和线路空载合载时的不平衡电流,从而降低动作门槛,大大提高保护的灵敏度和动作速度。最后本文使用了ATPDRAW和MATLAB软件对零序辅助选相法和电容电流补偿进行了仿真。
Current differential protection is an important developing direction of HV line main protection. This paper simply describes the basic tenets of current differential protection. Basic the principles of the tenets, this paper dose in-depth research about basic differential, fault component differential, zero-squence differential protection and current compensation. By analysis, it can be find that comparing with basic differential, the fault component will not be affected by load current and have higher sensitivity. Zero-squence differential can not be affected by transition resistance, it can rapid cut the fault. This paper puts forward a new fault phase selector of zero-squence differential protection. At the last chapter of this paper, this paper presents two current compensation methods of differential protection. The compensation method of current compensation can reduce the imbanlance current of external fault and unloaded switching, thereby reduce the action threshold, enhance the sensitivity and action speed of the protection greatly. Simulateing about fault phase selector of zero-squence differential protection and current compensation with ATPDRAW and MATLAB software also have in this paper.
Current differential protection is an important developing direction of HV line main protection. This paper simply describes the basic tenets of current differential protection. Basic the principles of the tenets, this paper dose in-depth research about basic differential, fault component differential, zero-squence differential protection and current compensation. By analysis, it can be find that comparing with basic differential, the fault component will not be affected by load current and have higher sensitivity. Zero-squence differential can not be affected by transition resistance, it can rapid cut the fault. This paper puts forward a new fault phase selector of zero-squence differential protection. At the last chapter of this paper, this paper presents two current compensation methods of differential protection. The compensation method of current compensation can reduce the imbanlance current of external fault and unloaded switching, thereby reduce the action threshold, enhance the sensitivity and action speed of the protection greatly. Simulateing about fault phase selector of zero-squence differential protection and current compensation with ATPDRAW and MATLAB software also have in this paper.
引文
[1] 李岩,陈德树,尹项根,等.超高压长线的分相纵差保护方案设计[J].电力系统自动化,2002,26(15):49-52.
[2] 高厚磊,江世芳,贺家李.输电线路新型电流差动保护的研究[J].中国电机工程学报,1999,19(8):49-53.
[3] 林湘宁,刘沛.全电流与故障分量电流比例差动判据的比较研究[J].中国电机工程学报,2004,24(10):27-31.
[4] 伍叶凯,邹东霞.电容电流对差动保护的影响及其补偿方案[J].继电器,1997,25(4):4-8.
[5] 毕天姝,于艳莉,黄少锋,等.超高压线路差动保护电容电流的精确补偿方法[J].电力系统自动化,2005,29(15):30-34.
[6] 索南加乐,张怿宁,齐军,等.∏模型时域电容电流补偿的电流差动保护研究[J].中国电机工程学报,2006,26(5):12-18.
[7] 郭征,贺家李.输电线纵联差动保护的新原理[J].电力系统自动化,2004,28(11):1-5.
[8] 郑玉平,吴通华,丁琰,等.基于贝瑞隆模型的线路差动保护实用判据[J].电力系统自动化,2004,28(23):50-55.
[9] 束洪春,高峰,陈学允,等.T型输电系统故障测距算法研究[J].中国电机工程学报,1998,18(6):416-420.
[10] Sachdev M S, Sidhu T S, Liu X. High-speed differential protection of parallel teed transmission lines[C]. In Proceedings of IEEE: WESCANEX 95. Communications Power and Computing conference, Winnipeg: 1995, vol.2: 495-500.
[11] 郭征,贺家李.三端线路光纤保护的研究[J].电力系统自动化,2003,27(10):57-59.
[12] 高厚磊,江世芳.T接线路电流纵差保护新判据研究[J].继电器,2001,29(9):6-9.
[13] 韩祯祥,吴国炎.电力系统分析[M].杭州:浙江大学出版社,1997.
[14] 朱声石.高压电网继电保护原理与技术[M].北京:中国电力出版社,2005.
[15] Mir M, Hasan Imam M. Limits to zones of simultaneous tripping in multi-terminal lines[C]. In: Developments in Power Protection. 1989, voll: 326-330.
[16] Ching-Shan Chen, Chih-Wen Liu, Joe-Air Jiang. Three-terminal transmission line protection using synchronized voltage and current phasor measurements[C]. In: Transmission and Distribution Conference and Exhibition. 2002, vol.3: 1727-1732.
[17] 文明浩,李瑞生,等.分相电流差动线路保护中的零序差动动作分析[J].继电器,2002,30(12):41-45.
[18] 伍叶凯,邹东霞.分相式微机电流差动保护灵敏度的研究[J].上海交通大学学报,1997,31(12):136-143.
[19] 袁荣湘,陈德树,等.基于相关分析的暂态电流差动保护的原理与性能研究[J].电网技术,2000,24(4):40-43.
[20] 高厚磊,江世芳.负荷电流对电流差动保护动作性能的影响分析[J].继电器,1999,27(1):14-17.
[21] 廖泽友,鲍伟廉,杨奇逊等.高压线路电流差动保护的现状及其前景展望[J].j继电器,1999,27(1):4-9.
[22] 吴通华,郑玉平,朱晓彤.基于暂态电容电流补偿的线路差动保护[J].电力系统自动化,2005,29(12):61-68.
[23] 索南加乐,张怿宁,齐军,等.基于时域电容电流补偿的电流差动保护研究[J].西安交通大学学报,2005,39(12):1370-1375.
[24] 胡玉峰,陈德树,伊项根.采样值差动及其应用[J].电力系统自动化,2000,25(5):40-45.
[25] 林湘宁,何战虎,刘世明等.复式电流比例差动保护判据的可靠性评估[J].中国电机工程学报,2001,21(7):98-103.
[26] 李晓华,张哲,尹项根.故障分量比率差动保护整定值的选取[J].电网技术,2001,25(4):47-51.
[27] 林湘宁,刘沛.全电流与故障分量电流比例差动判据的比较研究[J].中国电机工程学报,2004,24(10):27-32.
[28] 丁蕾,范春菊.高压地下电缆自适应继电保护方案的研究[J].继电器,2004,32(22):43-48.
[29] R. K Aggarwal, A. T ohns. A differential line protection scheme for power systems based on composite voltage and current measurements[C]. In: IEEE Transactions on Power Delivery, Vol.4, No.3, July1989.
[30] J. S Thorp, A. G. Phadke, S. H. Horoeitz, et al. Some applications of phasor measurements to adaptive protection[C]. In: IEEE Transations on Prower System, Vol.3, No.2, May1988.
[31] 袁荣湘,陈德树,张哲.高压输电线路新型差动保护的研究[J].中国电机工程学报,2000,20(4):9-14.
[32] 马文龙,郭效军,王文雄等.一种超高压输电线路自适应分相电流差动保护新原理研究[J].电力系统自动化设备,2004,24(12):12-16.
[33] F. Ghassemi, J. Goodarzi, A. T. Johns. Method to improve digital distance relay impedance measurement when used in series compensated lines protected by a metal oxide varistor[C]. In: IEEE Proc-Gener Transm Distrib, Vol.145, No.4, July 1998.
[34] 苏斌,董新洲,孙元章.适用于特高压线路的差动保护分布电容电流补偿算法[J].电力系统自动化,2005,29(8):36-42.
[35] 丁蕾,房鑫炎.基于电容电流半补偿的高压电力电缆分相电流差动保护研究[J].电网技术,2005,29(4):45-50.
[36] 陈德树,尹项根,张哲.再谈采样值差动保护的一些问题[J].电力自动化设备,2000,20(4):1-3.
[2] 高厚磊,江世芳,贺家李.输电线路新型电流差动保护的研究[J].中国电机工程学报,1999,19(8):49-53.
[3] 林湘宁,刘沛.全电流与故障分量电流比例差动判据的比较研究[J].中国电机工程学报,2004,24(10):27-31.
[4] 伍叶凯,邹东霞.电容电流对差动保护的影响及其补偿方案[J].继电器,1997,25(4):4-8.
[5] 毕天姝,于艳莉,黄少锋,等.超高压线路差动保护电容电流的精确补偿方法[J].电力系统自动化,2005,29(15):30-34.
[6] 索南加乐,张怿宁,齐军,等.∏模型时域电容电流补偿的电流差动保护研究[J].中国电机工程学报,2006,26(5):12-18.
[7] 郭征,贺家李.输电线纵联差动保护的新原理[J].电力系统自动化,2004,28(11):1-5.
[8] 郑玉平,吴通华,丁琰,等.基于贝瑞隆模型的线路差动保护实用判据[J].电力系统自动化,2004,28(23):50-55.
[9] 束洪春,高峰,陈学允,等.T型输电系统故障测距算法研究[J].中国电机工程学报,1998,18(6):416-420.
[10] Sachdev M S, Sidhu T S, Liu X. High-speed differential protection of parallel teed transmission lines[C]. In Proceedings of IEEE: WESCANEX 95. Communications Power and Computing conference, Winnipeg: 1995, vol.2: 495-500.
[11] 郭征,贺家李.三端线路光纤保护的研究[J].电力系统自动化,2003,27(10):57-59.
[12] 高厚磊,江世芳.T接线路电流纵差保护新判据研究[J].继电器,2001,29(9):6-9.
[13] 韩祯祥,吴国炎.电力系统分析[M].杭州:浙江大学出版社,1997.
[14] 朱声石.高压电网继电保护原理与技术[M].北京:中国电力出版社,2005.
[15] Mir M, Hasan Imam M. Limits to zones of simultaneous tripping in multi-terminal lines[C]. In: Developments in Power Protection. 1989, voll: 326-330.
[16] Ching-Shan Chen, Chih-Wen Liu, Joe-Air Jiang. Three-terminal transmission line protection using synchronized voltage and current phasor measurements[C]. In: Transmission and Distribution Conference and Exhibition. 2002, vol.3: 1727-1732.
[17] 文明浩,李瑞生,等.分相电流差动线路保护中的零序差动动作分析[J].继电器,2002,30(12):41-45.
[18] 伍叶凯,邹东霞.分相式微机电流差动保护灵敏度的研究[J].上海交通大学学报,1997,31(12):136-143.
[19] 袁荣湘,陈德树,等.基于相关分析的暂态电流差动保护的原理与性能研究[J].电网技术,2000,24(4):40-43.
[20] 高厚磊,江世芳.负荷电流对电流差动保护动作性能的影响分析[J].继电器,1999,27(1):14-17.
[21] 廖泽友,鲍伟廉,杨奇逊等.高压线路电流差动保护的现状及其前景展望[J].j继电器,1999,27(1):4-9.
[22] 吴通华,郑玉平,朱晓彤.基于暂态电容电流补偿的线路差动保护[J].电力系统自动化,2005,29(12):61-68.
[23] 索南加乐,张怿宁,齐军,等.基于时域电容电流补偿的电流差动保护研究[J].西安交通大学学报,2005,39(12):1370-1375.
[24] 胡玉峰,陈德树,伊项根.采样值差动及其应用[J].电力系统自动化,2000,25(5):40-45.
[25] 林湘宁,何战虎,刘世明等.复式电流比例差动保护判据的可靠性评估[J].中国电机工程学报,2001,21(7):98-103.
[26] 李晓华,张哲,尹项根.故障分量比率差动保护整定值的选取[J].电网技术,2001,25(4):47-51.
[27] 林湘宁,刘沛.全电流与故障分量电流比例差动判据的比较研究[J].中国电机工程学报,2004,24(10):27-32.
[28] 丁蕾,范春菊.高压地下电缆自适应继电保护方案的研究[J].继电器,2004,32(22):43-48.
[29] R. K Aggarwal, A. T ohns. A differential line protection scheme for power systems based on composite voltage and current measurements[C]. In: IEEE Transactions on Power Delivery, Vol.4, No.3, July1989.
[30] J. S Thorp, A. G. Phadke, S. H. Horoeitz, et al. Some applications of phasor measurements to adaptive protection[C]. In: IEEE Transations on Prower System, Vol.3, No.2, May1988.
[31] 袁荣湘,陈德树,张哲.高压输电线路新型差动保护的研究[J].中国电机工程学报,2000,20(4):9-14.
[32] 马文龙,郭效军,王文雄等.一种超高压输电线路自适应分相电流差动保护新原理研究[J].电力系统自动化设备,2004,24(12):12-16.
[33] F. Ghassemi, J. Goodarzi, A. T. Johns. Method to improve digital distance relay impedance measurement when used in series compensated lines protected by a metal oxide varistor[C]. In: IEEE Proc-Gener Transm Distrib, Vol.145, No.4, July 1998.
[34] 苏斌,董新洲,孙元章.适用于特高压线路的差动保护分布电容电流补偿算法[J].电力系统自动化,2005,29(8):36-42.
[35] 丁蕾,房鑫炎.基于电容电流半补偿的高压电力电缆分相电流差动保护研究[J].电网技术,2005,29(4):45-50.
[36] 陈德树,尹项根,张哲.再谈采样值差动保护的一些问题[J].电力自动化设备,2000,20(4):1-3.