计及调节增量的电压无功协调控制的研究
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摘要
电压是衡量电能质量的一个重要指标,电压的变化对用户的运行特性有很大的影响,而无功功率与电压水平有着密切的联系,无功功率在电力网络中的流动产生电压损耗,为了提高电压水平电力部门采用了多种措施调压措施,其中电压无功综合控制是变电站提高电压水平降损节能最有效的方法。本文从电压无功综合控制的基本原理出发,说明了变压器分接头的调节与并联电容器投入容量的大小对电网电压的影响。传统的电压无功控制不考虑变压器分接头和电容器组数调节所产生的电压和无功增量对调节控制的影响,容易产生的调节振荡,增加了系统受冲击的次数。针对这些问题本文提出了计及调节增量的电压无功协调控制方法,该方法计及在调节变压器分接头和无功补偿电容器组数时所产生的电压和无功功率的变化,从而,可准确地确定电压无功控制的控制目标,避免调节振荡。许多新型的电压无功控制策略引入了人工智能技术,但其在实现过程中存在着很多困难,并且没有达到真正意义上的控制目的一使网损达到最小。计及调节增量的电压无功协调控制综合考虑了改变变压器分接头与投切电容器的实际效果。由于在电压调节过程中随着系统电压的变化,线路电压损耗、负荷消耗的功率及电容器的无功出力将发生变化,因此,在电压的调节过程中通过考虑上述量的变化使调节更加准确、使网损达到最低,实现调节一次成功,从而降低了变压分接头开关的动作次数,增强了变压器运行可靠性。
本文根据现场的需求提出了以MCS96单片机为核心的硬件结构,提高了系统的数据处理能力。为了提高控制系统的安全与可靠性,加强了闭锁、保护功能的设计,确保当系统本身出现异常情况或电网中出现故障时保护装置能迅速动作。硬件、软件的设计上采取了多种措施增强系统的抗干扰能力。最后以模拟试验与实例仿真的结果验证了计及调节增量的电压无功协调控制策略具有良好的控制效果。
Voltage is one of important criterion to weigh the power quality,the change on voltage makes great effect on load opperating-characteristic,reactive power is near to voltage level,the flow of reactive power in transmission net causes voltage loss power institute take many measures to improve the voltage level,thereinto, voltage and reactive power integrated control is most effective measure to lessen the power loss and improve the voltage level.The basic theory for voltage and reactive control and the taps changed in transformer and shunt capacitor switched affect the voltage value are discussed in the paper.The oscillation is easily generated and the times is increased the power suffer impact because increment is ignored by traditional criterion for voltage and reactive control. The criterion of voltage and reactive power control considering the increment of adjusting is put forward corresponding to these problem in this paper,this criterion can confirm the adjusting object for voltage and reactive power co
ntrol exactly and can avoid the oscillation.Many new criterion have adopted artificial intelligence but it is difficult to realize them besides they can't really realize the controlling object-make the power loss reach to bottom.The power loss in line , the power assumption on load and the contribution of the shunt capacitor change when voltage is adjusted,so adjustment can be exactly realized and the times of taps changer when considering these increment.
In the hardware of this control system,the MCS96 single-chip-microcomputer system is adopted under demand of field,the ability of data processing is strengthened.In order to improve safety and reliability of control,the blocking is designed,when in the fault of the control system and the power system ,the protect set can make use.Many measures are used to anti-jamming in this design In the end of the this papers simulation experiment aml emulational example verify the fine effect of the criterion.
本文根据现场的需求提出了以MCS96单片机为核心的硬件结构,提高了系统的数据处理能力。为了提高控制系统的安全与可靠性,加强了闭锁、保护功能的设计,确保当系统本身出现异常情况或电网中出现故障时保护装置能迅速动作。硬件、软件的设计上采取了多种措施增强系统的抗干扰能力。最后以模拟试验与实例仿真的结果验证了计及调节增量的电压无功协调控制策略具有良好的控制效果。
Voltage is one of important criterion to weigh the power quality,the change on voltage makes great effect on load opperating-characteristic,reactive power is near to voltage level,the flow of reactive power in transmission net causes voltage loss power institute take many measures to improve the voltage level,thereinto, voltage and reactive power integrated control is most effective measure to lessen the power loss and improve the voltage level.The basic theory for voltage and reactive control and the taps changed in transformer and shunt capacitor switched affect the voltage value are discussed in the paper.The oscillation is easily generated and the times is increased the power suffer impact because increment is ignored by traditional criterion for voltage and reactive control. The criterion of voltage and reactive power control considering the increment of adjusting is put forward corresponding to these problem in this paper,this criterion can confirm the adjusting object for voltage and reactive power co
ntrol exactly and can avoid the oscillation.Many new criterion have adopted artificial intelligence but it is difficult to realize them besides they can't really realize the controlling object-make the power loss reach to bottom.The power loss in line , the power assumption on load and the contribution of the shunt capacitor change when voltage is adjusted,so adjustment can be exactly realized and the times of taps changer when considering these increment.
In the hardware of this control system,the MCS96 single-chip-microcomputer system is adopted under demand of field,the ability of data processing is strengthened.In order to improve safety and reliability of control,the blocking is designed,when in the fault of the control system and the power system ,the protect set can make use.Many measures are used to anti-jamming in this design In the end of the this papers simulation experiment aml emulational example verify the fine effect of the criterion.
引文
[1] 电力系统电压和无功电力管理条例,能源电【1988】18号
[2] 游国权,黄家焕,杨建新,龙小玲,广西电网无功电压问题及对策,广西电力技术,1996(4):1~8
[3] 程昊,杨强等,云南电网无功电压运行情况调查研究,云南电力技术,2002.9(3):4~7
[4] 李锐,无功电压自动调节的实现方式及发展方向,继电器,2003.8(8):72~74
[5] 隋挣有,中低压配网实用技术,北京:机械工业出版社,2000.12
[6] 苏文成,金子康,无功补偿与电力电子技术,机械工业出版社,1989.7
[7] 王兆安,杨君,刘进军,谐波抑制和无功功率补偿,北京:机械工业出版社,1998.9
[8] 赵家礼,张庆达,变压器故障诊断与修理,北京:机械工业出版社,1998.9
[9] 李致恒,李海钧,陆孟君,城乡电网无功补偿技术,北京:水利电力出版社,1989.12
[10] 马维新,电力系统电压,北京:中国电力出版社,1998.4
[11] 姚志松,姚磊,有载分接开关实用手册,北京:中国电力出版社,2003.1
[12] 孙涵芳,Intel 16位单片机,北京:北京航空航天大学出版社,1995.11
[13] 刘乐善,微型计算机接口技术及应用,武汉:华中科技大学出版社,2000.4
[14] 电力系统电压质量和无功电力规定(试行),能源电【1993】218号
[15] 电力系统电压和无功电力技术导则(试行),SD325-1989
[16] 低压无功补偿控制器订货技术条件,DL/T 597-1996
[17] 标称电压1kV以上交流电力系统用并联电容器 第3部分:并联电容器和并联电容器组保护,GB/Z 11024.3-2001
[18] 高压并联电容器装置订货技术条件,DL/T 604-1996
[19] 变电所电压无功调节控制装置订货技术条件,DL/T 672-1999
[20] 忻俊慧,湖北电网无功电压存在的主要问题及建议,中国电力,1997(10):68~69
[21] 奚江慧,凌卫家,简论华中电网电压质量及无功电压管理工作,华中电力,2002增刊(15):26~29
[22] 张建设,张福轩,山西中低压电网电压无功问题调查及对策,华北电力技术,2000(4):34~36
[23] 赵旺初,有载调压开关的几个问题,高电压技术,1995.1(2):81~82
[24] 张德明,有载分接开关国内现状及其发展动向,变压器,2000.1(1):36~39
[25] 盛戈皞,涂光瑜,罗毅,人工智能技术在电力系统无功电压控制中的应用,电网技术,2002.6(6):22~27
[26] 张红,王诚梅,电力系统常用交流采样算法比较,山东电力技术,1999(1):64~67
[27] 黄纯,何怡刚,江亚群,彭建春,交流采样同步方法的分析与改进,中国电机工程学报,2002.9(9):38~42
[28] 顾正昌,数据采集系统与软件抗干扰措施,电气自动化,2001(1):39~42
[29] 张辉,浅谈微机控制中的滤波方法,丹东师专学报,2000.11(总第82):30~31
[30] 汪胜聪,滕勤,左承基,综述单片机控制系统的抗干扰设计,现代电子技术,2003(1):7~9
[31] 裘云,王健,软件同步采样实现方法的比较与选择,仪表技术,2000(4):19~21
[32] 何瑞文,晶闸管静止自动有载调压的研究,应用技术,1997(1):11~16
[33] 李晓明,黄俊杰等,平滑无冲击电力电子有载调压装置,电力系统自动化,2003.10(20):45~48
[34] 陈芳,李儒,吴珊珊,浅谈有载调压变压器在电力系统中的应用,广东电力,1999.8(4):62~63
[35] 陈红兵,串联电容器在电网中的调压作用及工程应用,电气工程应用,2000(2):31~33
[36] 蔡宏毅,电力系统的无功电压与调压措施,吉林电力技术,1989(6):7~10
[37] 历吉文,潘贞存等,变电所电压和无功自动调节判据的研究,中国电力,1995(7):12~16
[38] 苏建元,王柏林,洪佩孙,变电站电压无功优化控制器,河海大学学报,1998.7(4):107~110
[39] 严浩军,变电站电压无功综合控制策略的改进,电网技术,1997.10(10):47~49
[40] 王正风,徐先勇,浅谈电力系统的无功优化和无功补偿,华东电力,2002(11):13~15
[41] 严浩军,变电站电压无功综合自动控制问题探讨,电网技术,2000.7(7):41~44:1
[42] 张明军,董洁,蒋霞等,电压无功综合调节判据的分析,山东大学学报,2003.2(1):22~24
[43] 凌皖疆,方自力,电网实施无功/电压优化控制,四川电力技术,2003(1):51~53
[44] 丁恰,李乃湖,武寒,电压无功功率优化控制中不可行问题的研究,电网技术,1999.9(9):19~22
[45] 刘志超,陈宏钟,张伟等,基于专家系统的变电站电压无功控制装置,电力系统自动化,2003.1(2):74~77
[46] 赵登福,司,杨靖等,新型变电站电压无功综合控制装置的研制,电网技术,
2000.3(6):14~17
[47] 晏家进,有载调压变压器的级电压选择,供用电,1994(2):24~25
[48] 杜红卫,寥志伟,杨庆早等,智能型变电站电压、无功综合自动控制装置,电力自动化设备,2001.2(2):42~44
[49] 吕艳萍,变电所自动调压装置的专家系统,中国电力,1996(3):48~51
[50] 苏泽光,变电站电压无功控制研究,电力自动化设备,2001.12(12):19~22
[51] 杨安东,辐射式电网无功电压优化集中控制的一种实用方法,供电技术,2003(1):40~41
[52] 刘志超,陈宏钟,张伟等,基于专家系统的变电站电压无功控制装置,电力系统自动化,2003.1(2):74~77
[53] 张尧,宋文南,贺家李,专家系统用于无功、电压在线控制,天津大学学报,1993(1):23~29
[54] 许之晗,刘小川,刘俊勇等,变电站电压无功模糊控制系统的研究,电力自动化设备,2001.3(3):15~19
[55] 李建中,变电站电压无功综合模糊控制研究,中国电力,1998(4):43~45
[56] 陈远华,秦荃华,杨晓红等,基于模糊边界无功调节判据的电压无功综合控制,中国电力,2002.10(10):50~53
[57] 李亚男,张粒子,苏隽等,结合专家知识的遗传算法在无功规划优化中的应用,电网技术,2001.7(7):14~17
[58] 何南强,刘予丹,具有自辩识功能的模糊自动电压无功控制装置,电网技术,2000.4(4):52~56
[59] 段海峰,李兴源,宋永华,一种基于模糊逻辑的电压无功控制策略,电力系统自动化,1997.6(6):32~34
[60] 刘建强,配电网四种无功补偿技术方案比较,电工技术杂志,2003(3):30~34
[61] 杨争林,孙雅明,基于ANN的变电站电压和无功综合自动控制,电力系统自动化,1999.7(13):10~13
[62] 周忠福,杜翠卿,高曙,基于模糊神经网络的变电站电压/无功控制方法,现代电力 1998.11(11):13~18
[63] 苏永春,陈星莺,刘存凯,基于遗传算法的变电站电压无功综合控制,继电器,2002.15(10):11~13
[64] 赵彩虹,马晓光,基于遗传算法的局部电压分域新方法,电网技术,2002.9(9):47~50
[65] Borozan. V, Baran. M. E, Novose. D, Integrated volt/VAr control in distribution systems, Power Engineering Society Winter Meeting, IEEE, 2001: 1485~1490
[66] Yutian Liu, Peng Zhang, Xizhao Qiu, Optimal reactive power and voltage control for radial distribution system, Power Engineering Society Summer Meeting, IEEE, 2000: 85~90
[67] Chien-Ning Yu, Yong T. Yoon, On-line voltage regulation: the case of New England, IEEE Transactions on Power Systems, 1999. 11(4): 1477~1484
[68] Corsi. S, The secondary. voltage regulation in Italy, Power Engineering Society Summer Meeting, 2000. IEEE: 296~304
[69] Girotti. T. B, Tweed. N. B, Houser. N. R, Real-time VAr control by SCADA, IEEE Transactions on Power Systems, 1990. 2:61~64
[70] Hong. Y. Y, Yang. Y. L, Expert system for enhancing voltage security/stability in power systems, Generation, Transmission and Distribution, IEEE Proceedings 1999. 4:349~354
[71] Echavarria. R, Cotorogea. M, Design and implementation of a fast on-load tap changing regulator, Industry Applications Conference, IEEE 2000:2078~2085
[72] Bansilal, Thukaram. D, Parthasarathy. K, An expert system for voltage control in a power system network, Energy Management and Power Delivery, 1995. Proceedings of EMPD'95.: 364~369
[73] Ruey-Hsun Liang, Yung-Shuen Wang, Fuzzy-based reactive power and voltage control in a distribution system, IEEE Transactions on Power Delivery, 2003:610~618
[74] Vu. H, Pruvot. P, Launay. C, An improved voltage control on large-scale power system, IEEE Transactions on Power Systems, 1996. 8: 1295~1303
[75] Ramos. J. L. M, Exposito. A. G, Cerezo. J. C, A hybrid tool to assist the operator in reactive power/voltage control and optimization, IEEE Transactions on Power Systems, 1995. 5:760~768
[76] Salem. M. R, Talat. L. A. Soliman, Voltage control by tap-changing transformers for a radial distribution network, Generation, Transmission and Distribution, IEE Proceedings, 1997. 11: 517~520
[77] Pimpa. C, Premrudeepreechacham. S, Voltage control in power system using expert system based on SCADA system, Power Engineering Society Winter Meeting, IEEE, 2002:1282~1286
[78] Lba. K, Reactive power optimization by genetic algorithm, IEEE Transactions on Power Systems, 1994. 5:685~692
[79] Abdul-Rahman. K. H, Shahidehpour. S. M, Reactive power optimization using fuzzy load representation, IEEE Transactions on Power Systems, 1994. 5:898~905
[80] Lba. K, Reactive power optimization by genetic algorithm, Power Industry Computer Application Conference, 1993: 195~201
[81] 高能,艾红,单片机抗干扰技术,辽宁师专学报,2001.3(1):32~36
[82] 杨志敏,李晔,开关电源的EMC设计,移动电源与车辆,2002(1):11~13
[83] 丁小东,电子设备的接地和接地设计,环境技术,2001(1):32~34
[84] 侯志伟,对接地技术几个问题的探讨,重庆建筑大学学报,2000.6(3):81~84
[85] 杨继深,旬京京,电磁干扰的抑制方法(上),电磁干扰抑制技术,1998(1):8~15
[86] 杨继深,旬京京,电磁干扰的抑制方法(中),电磁干扰抑制技术,1998(2):18~21
[87] 杨继深,旬京京,电磁干扰的抑制方法(下),电磁干扰抑制技术,1998(3):22~25
[2] 游国权,黄家焕,杨建新,龙小玲,广西电网无功电压问题及对策,广西电力技术,1996(4):1~8
[3] 程昊,杨强等,云南电网无功电压运行情况调查研究,云南电力技术,2002.9(3):4~7
[4] 李锐,无功电压自动调节的实现方式及发展方向,继电器,2003.8(8):72~74
[5] 隋挣有,中低压配网实用技术,北京:机械工业出版社,2000.12
[6] 苏文成,金子康,无功补偿与电力电子技术,机械工业出版社,1989.7
[7] 王兆安,杨君,刘进军,谐波抑制和无功功率补偿,北京:机械工业出版社,1998.9
[8] 赵家礼,张庆达,变压器故障诊断与修理,北京:机械工业出版社,1998.9
[9] 李致恒,李海钧,陆孟君,城乡电网无功补偿技术,北京:水利电力出版社,1989.12
[10] 马维新,电力系统电压,北京:中国电力出版社,1998.4
[11] 姚志松,姚磊,有载分接开关实用手册,北京:中国电力出版社,2003.1
[12] 孙涵芳,Intel 16位单片机,北京:北京航空航天大学出版社,1995.11
[13] 刘乐善,微型计算机接口技术及应用,武汉:华中科技大学出版社,2000.4
[14] 电力系统电压质量和无功电力规定(试行),能源电【1993】218号
[15] 电力系统电压和无功电力技术导则(试行),SD325-1989
[16] 低压无功补偿控制器订货技术条件,DL/T 597-1996
[17] 标称电压1kV以上交流电力系统用并联电容器 第3部分:并联电容器和并联电容器组保护,GB/Z 11024.3-2001
[18] 高压并联电容器装置订货技术条件,DL/T 604-1996
[19] 变电所电压无功调节控制装置订货技术条件,DL/T 672-1999
[20] 忻俊慧,湖北电网无功电压存在的主要问题及建议,中国电力,1997(10):68~69
[21] 奚江慧,凌卫家,简论华中电网电压质量及无功电压管理工作,华中电力,2002增刊(15):26~29
[22] 张建设,张福轩,山西中低压电网电压无功问题调查及对策,华北电力技术,2000(4):34~36
[23] 赵旺初,有载调压开关的几个问题,高电压技术,1995.1(2):81~82
[24] 张德明,有载分接开关国内现状及其发展动向,变压器,2000.1(1):36~39
[25] 盛戈皞,涂光瑜,罗毅,人工智能技术在电力系统无功电压控制中的应用,电网技术,2002.6(6):22~27
[26] 张红,王诚梅,电力系统常用交流采样算法比较,山东电力技术,1999(1):64~67
[27] 黄纯,何怡刚,江亚群,彭建春,交流采样同步方法的分析与改进,中国电机工程学报,2002.9(9):38~42
[28] 顾正昌,数据采集系统与软件抗干扰措施,电气自动化,2001(1):39~42
[29] 张辉,浅谈微机控制中的滤波方法,丹东师专学报,2000.11(总第82):30~31
[30] 汪胜聪,滕勤,左承基,综述单片机控制系统的抗干扰设计,现代电子技术,2003(1):7~9
[31] 裘云,王健,软件同步采样实现方法的比较与选择,仪表技术,2000(4):19~21
[32] 何瑞文,晶闸管静止自动有载调压的研究,应用技术,1997(1):11~16
[33] 李晓明,黄俊杰等,平滑无冲击电力电子有载调压装置,电力系统自动化,2003.10(20):45~48
[34] 陈芳,李儒,吴珊珊,浅谈有载调压变压器在电力系统中的应用,广东电力,1999.8(4):62~63
[35] 陈红兵,串联电容器在电网中的调压作用及工程应用,电气工程应用,2000(2):31~33
[36] 蔡宏毅,电力系统的无功电压与调压措施,吉林电力技术,1989(6):7~10
[37] 历吉文,潘贞存等,变电所电压和无功自动调节判据的研究,中国电力,1995(7):12~16
[38] 苏建元,王柏林,洪佩孙,变电站电压无功优化控制器,河海大学学报,1998.7(4):107~110
[39] 严浩军,变电站电压无功综合控制策略的改进,电网技术,1997.10(10):47~49
[40] 王正风,徐先勇,浅谈电力系统的无功优化和无功补偿,华东电力,2002(11):13~15
[41] 严浩军,变电站电压无功综合自动控制问题探讨,电网技术,2000.7(7):41~44:1
[42] 张明军,董洁,蒋霞等,电压无功综合调节判据的分析,山东大学学报,2003.2(1):22~24
[43] 凌皖疆,方自力,电网实施无功/电压优化控制,四川电力技术,2003(1):51~53
[44] 丁恰,李乃湖,武寒,电压无功功率优化控制中不可行问题的研究,电网技术,1999.9(9):19~22
[45] 刘志超,陈宏钟,张伟等,基于专家系统的变电站电压无功控制装置,电力系统自动化,2003.1(2):74~77
[46] 赵登福,司,杨靖等,新型变电站电压无功综合控制装置的研制,电网技术,
2000.3(6):14~17
[47] 晏家进,有载调压变压器的级电压选择,供用电,1994(2):24~25
[48] 杜红卫,寥志伟,杨庆早等,智能型变电站电压、无功综合自动控制装置,电力自动化设备,2001.2(2):42~44
[49] 吕艳萍,变电所自动调压装置的专家系统,中国电力,1996(3):48~51
[50] 苏泽光,变电站电压无功控制研究,电力自动化设备,2001.12(12):19~22
[51] 杨安东,辐射式电网无功电压优化集中控制的一种实用方法,供电技术,2003(1):40~41
[52] 刘志超,陈宏钟,张伟等,基于专家系统的变电站电压无功控制装置,电力系统自动化,2003.1(2):74~77
[53] 张尧,宋文南,贺家李,专家系统用于无功、电压在线控制,天津大学学报,1993(1):23~29
[54] 许之晗,刘小川,刘俊勇等,变电站电压无功模糊控制系统的研究,电力自动化设备,2001.3(3):15~19
[55] 李建中,变电站电压无功综合模糊控制研究,中国电力,1998(4):43~45
[56] 陈远华,秦荃华,杨晓红等,基于模糊边界无功调节判据的电压无功综合控制,中国电力,2002.10(10):50~53
[57] 李亚男,张粒子,苏隽等,结合专家知识的遗传算法在无功规划优化中的应用,电网技术,2001.7(7):14~17
[58] 何南强,刘予丹,具有自辩识功能的模糊自动电压无功控制装置,电网技术,2000.4(4):52~56
[59] 段海峰,李兴源,宋永华,一种基于模糊逻辑的电压无功控制策略,电力系统自动化,1997.6(6):32~34
[60] 刘建强,配电网四种无功补偿技术方案比较,电工技术杂志,2003(3):30~34
[61] 杨争林,孙雅明,基于ANN的变电站电压和无功综合自动控制,电力系统自动化,1999.7(13):10~13
[62] 周忠福,杜翠卿,高曙,基于模糊神经网络的变电站电压/无功控制方法,现代电力 1998.11(11):13~18
[63] 苏永春,陈星莺,刘存凯,基于遗传算法的变电站电压无功综合控制,继电器,2002.15(10):11~13
[64] 赵彩虹,马晓光,基于遗传算法的局部电压分域新方法,电网技术,2002.9(9):47~50
[65] Borozan. V, Baran. M. E, Novose. D, Integrated volt/VAr control in distribution systems, Power Engineering Society Winter Meeting, IEEE, 2001: 1485~1490
[66] Yutian Liu, Peng Zhang, Xizhao Qiu, Optimal reactive power and voltage control for radial distribution system, Power Engineering Society Summer Meeting, IEEE, 2000: 85~90
[67] Chien-Ning Yu, Yong T. Yoon, On-line voltage regulation: the case of New England, IEEE Transactions on Power Systems, 1999. 11(4): 1477~1484
[68] Corsi. S, The secondary. voltage regulation in Italy, Power Engineering Society Summer Meeting, 2000. IEEE: 296~304
[69] Girotti. T. B, Tweed. N. B, Houser. N. R, Real-time VAr control by SCADA, IEEE Transactions on Power Systems, 1990. 2:61~64
[70] Hong. Y. Y, Yang. Y. L, Expert system for enhancing voltage security/stability in power systems, Generation, Transmission and Distribution, IEEE Proceedings 1999. 4:349~354
[71] Echavarria. R, Cotorogea. M, Design and implementation of a fast on-load tap changing regulator, Industry Applications Conference, IEEE 2000:2078~2085
[72] Bansilal, Thukaram. D, Parthasarathy. K, An expert system for voltage control in a power system network, Energy Management and Power Delivery, 1995. Proceedings of EMPD'95.: 364~369
[73] Ruey-Hsun Liang, Yung-Shuen Wang, Fuzzy-based reactive power and voltage control in a distribution system, IEEE Transactions on Power Delivery, 2003:610~618
[74] Vu. H, Pruvot. P, Launay. C, An improved voltage control on large-scale power system, IEEE Transactions on Power Systems, 1996. 8: 1295~1303
[75] Ramos. J. L. M, Exposito. A. G, Cerezo. J. C, A hybrid tool to assist the operator in reactive power/voltage control and optimization, IEEE Transactions on Power Systems, 1995. 5:760~768
[76] Salem. M. R, Talat. L. A. Soliman, Voltage control by tap-changing transformers for a radial distribution network, Generation, Transmission and Distribution, IEE Proceedings, 1997. 11: 517~520
[77] Pimpa. C, Premrudeepreechacham. S, Voltage control in power system using expert system based on SCADA system, Power Engineering Society Winter Meeting, IEEE, 2002:1282~1286
[78] Lba. K, Reactive power optimization by genetic algorithm, IEEE Transactions on Power Systems, 1994. 5:685~692
[79] Abdul-Rahman. K. H, Shahidehpour. S. M, Reactive power optimization using fuzzy load representation, IEEE Transactions on Power Systems, 1994. 5:898~905
[80] Lba. K, Reactive power optimization by genetic algorithm, Power Industry Computer Application Conference, 1993: 195~201
[81] 高能,艾红,单片机抗干扰技术,辽宁师专学报,2001.3(1):32~36
[82] 杨志敏,李晔,开关电源的EMC设计,移动电源与车辆,2002(1):11~13
[83] 丁小东,电子设备的接地和接地设计,环境技术,2001(1):32~34
[84] 侯志伟,对接地技术几个问题的探讨,重庆建筑大学学报,2000.6(3):81~84
[85] 杨继深,旬京京,电磁干扰的抑制方法(上),电磁干扰抑制技术,1998(1):8~15
[86] 杨继深,旬京京,电磁干扰的抑制方法(中),电磁干扰抑制技术,1998(2):18~21
[87] 杨继深,旬京京,电磁干扰的抑制方法(下),电磁干扰抑制技术,1998(3):22~25