电容型设备介质损耗因数在线检测技术的研究
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摘要
电力设备绝缘检测是保证安全发、配电,及时发现事故隐患、提高供电可靠性的重要技术手段。随着电力事业的迅速发展以及对电力系统运行可靠性要求的进一步提高,电气设备在线检测技术的发展日益得到重视。高压电容型设备在变电站中占有相当大的比例,而介质损耗因数(tan δ)是反映其绝缘状况的重要参数。因此,研究电容型设备的tan δ在线检测技术具有十分重要的意义。
采样系统的性能对数字化介质损耗测量的精度有非常重要的影响,文中结合谐波分析法介质损耗在线检测的特点和要求,对影响采样系统性能的主要参数——采样位数和采样频率进行了详细的分析,得出了它们对测量误差的影响规律,并在此基础上给出了确定最佳采样频率和采样位数的原则和方法。
为了更好地保证tan δ在线检测的准确性,文中把数字滤波技术应用于tan δ在线检测,利用布莱克曼窗函数的设计方法设计了有限长冲激响应的数字滤波器,仿真表明该滤波器具有良好的滤波效果。
文中针对国内外在进行电容型设备介质损耗因数在线检测研究中存在的技术难点,如电网基波频率不稳、高次谐波干扰、现场电磁干扰等问题,提出了将加窗插值的快速傅立叶变换算法应用于tan δ测量。这种方法与传统的快速傅立叶变换算法相比,避免了由于基波频率提取不准而造成的频谱泄漏,在一定的基波频率变化范围内具有较高的精度。
本文在研究以上理论问题的基础上,本着准确度高、实用性强、成本低、可靠性好的原则,研制了一种电容型设备tan δ在线检测装置。在对装置进行设计的过程中,通过对各个环节进行理论分析和对部分环节进行仿真计算,使装置的设计结果达到了预期的设计目标。
The on-line insulation monitoring of power apparatus is very important to guarantee the safety of power delivery, find insulation faults in time and increase the reliability of power supply. With the development of electrical engineering and the further demand on the service reliability of power systems, the on-line insulation monitoring has been put more value on. high voltage capacitive-type equipment plays a very important role in power systems, and dielectric loss tangent (tan5) is an important parameter to reflect its insulation condition. Therefore, the study on the on-line tan5 monitoring of high voltage capacitive-type equipment has practical values.
The measured results are greatly influenced by the property of the wave sampling system. Two parameters: sampling accuracy and sampling frequency, which are the most important ones for sampling system, are discussed deeply. The way how these two parameters affect the performance of sampling system is concluded. On the basis of these, the principle and the method of determining the optimal sampling parameters are presented.
For the sake of assuring the accuracy of the measured results of tan8 better, digital filtering algorithm is introduced to the measurement of tan8. A kind of FIR digital filter is designed, simulation indicates that the designed filer has satisfying effect.
Considering the difficulties of on-line monitoring research of the high voltage capacitive-type equipment local and overseas, such as the excursion of the fundamental wave of power system, the existence of the harmonics and the electromagnetic interference, Windows and Interpolation Fast Fourier Transform algorithm is applied to the measurement of tan. With this method, the spectrum leakage can be avoided more effectively than Fast Fourier Transform algorithm and better accuracy can be assured in certain frequency range.
On the basis of the study of the theories above, a kind of on-line tan 5 monitoring system of high voltage capacitive-type equipment is developed which follows the principles of high accuracy, strong utility, low cost and high reliability. During the designing, every step is analyzed theoretically and parts of steps are simulated, the design of the monitoring system obtains anticipated purpose.
采样系统的性能对数字化介质损耗测量的精度有非常重要的影响,文中结合谐波分析法介质损耗在线检测的特点和要求,对影响采样系统性能的主要参数——采样位数和采样频率进行了详细的分析,得出了它们对测量误差的影响规律,并在此基础上给出了确定最佳采样频率和采样位数的原则和方法。
为了更好地保证tan δ在线检测的准确性,文中把数字滤波技术应用于tan δ在线检测,利用布莱克曼窗函数的设计方法设计了有限长冲激响应的数字滤波器,仿真表明该滤波器具有良好的滤波效果。
文中针对国内外在进行电容型设备介质损耗因数在线检测研究中存在的技术难点,如电网基波频率不稳、高次谐波干扰、现场电磁干扰等问题,提出了将加窗插值的快速傅立叶变换算法应用于tan δ测量。这种方法与传统的快速傅立叶变换算法相比,避免了由于基波频率提取不准而造成的频谱泄漏,在一定的基波频率变化范围内具有较高的精度。
本文在研究以上理论问题的基础上,本着准确度高、实用性强、成本低、可靠性好的原则,研制了一种电容型设备tan δ在线检测装置。在对装置进行设计的过程中,通过对各个环节进行理论分析和对部分环节进行仿真计算,使装置的设计结果达到了预期的设计目标。
The on-line insulation monitoring of power apparatus is very important to guarantee the safety of power delivery, find insulation faults in time and increase the reliability of power supply. With the development of electrical engineering and the further demand on the service reliability of power systems, the on-line insulation monitoring has been put more value on. high voltage capacitive-type equipment plays a very important role in power systems, and dielectric loss tangent (tan5) is an important parameter to reflect its insulation condition. Therefore, the study on the on-line tan5 monitoring of high voltage capacitive-type equipment has practical values.
The measured results are greatly influenced by the property of the wave sampling system. Two parameters: sampling accuracy and sampling frequency, which are the most important ones for sampling system, are discussed deeply. The way how these two parameters affect the performance of sampling system is concluded. On the basis of these, the principle and the method of determining the optimal sampling parameters are presented.
For the sake of assuring the accuracy of the measured results of tan8 better, digital filtering algorithm is introduced to the measurement of tan8. A kind of FIR digital filter is designed, simulation indicates that the designed filer has satisfying effect.
Considering the difficulties of on-line monitoring research of the high voltage capacitive-type equipment local and overseas, such as the excursion of the fundamental wave of power system, the existence of the harmonics and the electromagnetic interference, Windows and Interpolation Fast Fourier Transform algorithm is applied to the measurement of tan. With this method, the spectrum leakage can be avoided more effectively than Fast Fourier Transform algorithm and better accuracy can be assured in certain frequency range.
On the basis of the study of the theories above, a kind of on-line tan 5 monitoring system of high voltage capacitive-type equipment is developed which follows the principles of high accuracy, strong utility, low cost and high reliability. During the designing, every step is analyzed theoretically and parts of steps are simulated, the design of the monitoring system obtains anticipated purpose.
引文
[1] 郭剑波.“八五”期间电网事故统计分析[J].电网技术,98,22(2):72~74.
[2] 王秉仁,葛祥.变电站绝缘在线监测系统[J].电站系统工程,2002,18(1):57~59.
[3] 赵玉林,周启龙.高电压技术[M].北京:机械工业出版社,1997.42-47.
[4] 刘涤尘.电气工程基础[M].武汉理工大学出版社,2002.382-390.
[5] 王乃庆.绝缘在线监测技术的实用性、经济性和可靠性[J].电网技术,1995,19(11):54~56.
[6] 陈化刚.电气设备预防性试验方法[M].北京:水利电力出版社,1994.
[7] 东俊禄,吴旭涛,严南征,等.电容型设备介质损耗带电测试可行性研究[J].西北电力技术,2002,4:31~33.
[8] 王楠,律方成.基于小波变换的介损在线监测数据趋势提取[J].高电压技术,2003,29(3):31~33.
[9] 郭碧红,杨晓洪.我国电力设备在线监测技术的开发应用状况分析[J].电网技术,1999,23(8):65~68.
[10] 林建龙,邓敏,林力辉.高压绝缘设备在线监测系统[J].电网技术,2002,26(1):86~88.
[11] 戴昌彬,洪贞贤.电容型试品介质损耗因数变化的原因与分析[J].变压器,2002,39(9):38~41.
[12] 张泽华.电容型设备介损的带电测试对比分析[J].高电压技术,2001,27(104):83~84.
[13] Zhang Guyin. Calculation and Analysis of Effectiveness of Measuring Parameters during On-line Diagnosing Capacitive-type Insulation[C]. Second Sino-Japanese Conference on Electric Insulation Diagnosis, Shanghai, china, 1992. 129—132.
[14] Wang Jinhan. On-line Measurement of C_x and Tan δ on the Type of Capacitive Electric Equipment[J]. Proceeding of 1994 International Joint Conference, Osaka, Japan, 1994. 447—450.
[15] 朱德恒,严璋.高电压绝缘[M].北京:清华大学出版社,1992.262-263.
[16] 严璋.电气绝缘在线检测技术[M].北京:水利电力出版社,1995.
[17] 陈化刚.电气设备预防性试验方法[M].北京:水利电力出版社,1994.
[18] 周武仲.电力设备维修诊断玉预防性试验[M].北京:中国电力出版社,2002.
[19] 王卫周,吴集光,张菊鹏,等.介质损耗因数的自动数字测量系统[J].电子技术应用,2001,2:34~35.
[20] Rabiner L R, GoldB. Theory and Application of Digital Signal Processing[M]. Prentice-Hall, Inc., Englewood Cliffs,N.J., 1975. 53-140.
[21] 林国庆,陈桂龙.介质损耗数字化测量方法研究[J].计算机测量与控制,2002,10(4):217~219.
[22] Ding pinnan, Zhao Erdong. Digital Measurement Technique of Dielectric Loss Angle
Tangent[C]. Second Sino-Japanese on Electric Insulation Diagnosis, Shanghai, China, 1992. 133—135.
[23] Nitaigour, Premchand, Maholik. A Digital Meter for Measuring Dissipation Factor[C]. Proceedings Of the 5th International Conference on Properties and Applications of Dielectric Materials, Seoul, Korea, 1997. 1129—1131.
[24] Guan Genzhi, He Jingliang, Chen pengyun, et al. A Study on the On-line Monitoring and Measuring System for Electric Equipment Insulation in HV Substations[C]. Proceeding of 1994 International Joint Conference, Osaka, Japan, 1994. 287—290.
[25] 曹宇亚,申忠如,任稳柱.介质损耗带电检测数字化处理方法的研究[J].高压电器,2000,3:17~19.
[26] 吕延锋,钟连宏,王建华.电气设备绝缘介质损耗测量方法的研究[J].高电压技术,2001,26(5):38~42.
[27] Mahmud SM. Error Analysis of Digital Phase Measurement of Distorted Waves[J]. IEEE Tans I&M, 1989, 38(1): 6~8.
[28] Allan D M, Boyd K J, Hinde D D. A Continuous Insulation Monitor for High Voltage Transformer Bushings[C]. 7th ISH, German, 1991. 119-122.
[29] 金之俭,肖登明,王耀德.绝缘介质损耗角的数字化测量研究[J].高电压技术,1999,25:49~50.
[30] 蔡国雄,甄为红,杨晓洪,等.测量介质损耗的数字化过零点电压比较法[J].电网技术,2002,26(7):15~18.
[31] Cai Guoxiong. The On-line Dielectric Loss Measurement by Voltage Comparator Method[C]. Proceeding of 1994 International Joint Conference, Osaka, Japan, 1994. 127—130.
[32] 赵秀山,谈克雄,朱德恒,等.介质损耗角的数字化测量[J].清华大学学报,2001,36(9):51~56.
[33] 夏胜国,文远芳.高电压绝缘的Tan δ数字测量方法[J].高压电器,2000,2:38-41.
[34] 王楠,律方成,李艳涛,等.影响介损在线检测准确性的因素分析与探讨[J].电工技术杂志,2003,1:43~45.
[35] 尚勇,杨敏中,王晓蓉,等.谐波分析法介质损耗因数测量的误差分析[J].电工技术学,2002,17(3):67~71.
[36] Allan D M, Blundell M S, Boyd K J, et al. New Insulation Diagnostic and Monitoring Techniques for In-Service HV Apparatus[C]. Proceeding of the 3th International Conference on Properties and Applications of Dielectric Materials, Japan, 1991. 448—451.
[37] Allan D M, Blundell M S, Boyd K J, et al. New Techniques for Monitoring the Insulation Quality of In-service HV Apparatus[J]. IEEE Trans. On Electrical Insulation, 1992, 27(3): 578~585.
[38] Vujovic P, Fricker R P. Development of an on-line continuous Tan δ monitoring system[C]. Conference Record of the 1994 IEEE international symposium on electrical
insulation, ittsburgh USA, 1994. 50-53.
[39] Fricker R K. Monitoring HV Insulation Integrity On-line[J]. Transmission & Distribution World, 1996, 26~37.
[40] 黄新红.Tan δ在线检测技术的研究高压电容型设备[D].西安:西安交通大学1997.
[41] 何循来.高性能八位单片机AT89C5l[J].半导体技术,1997,4:61~63.
[42] 黄本雄,黄沛然,李姣军.高电压设备绝缘在线监测电流传感器的研究[J].华中理工大学学报,1996,24(5):1~2.
[43] 贾逸梅,粟福珩,刘军.一种新型高压电气设备在线绝缘监测系统[J].现代电力,2001,18(2):50~54.
[44] 绝缘在线监测的耳目[EB/OL].http://www.hamsss.com/index.htm.
[45] 中国计量科学研究院.Nonlinear-NS型系列泄漏电流传感器[EB/OL].http://www.Nature.ac.cn/xldlchgq.html.
[46] 西南自动化研究所.WB系列电量隔离传感器简明手册[M].1998.
[47] WB交流电量隔离传感器/变送器[EB/OL].http://www.honeywell-sensor.com.cn/prodinfo/Sensor current/datasheet/close loop curren t csn.pdf.
[48] 一种实用的线性隔离检测电路[EB/OL].http://www.china-power.net/dzkw/00-11/15.htm.
[49] 冯矞云.应启珩,陆延丰,等.模拟和数字滤波器的设计与实现[M].北京:人民邮电出版社,1985.
[50] 童诗白.模拟电子技术基础[M].北京:高等教育出版社,1998.
[51] 胡广书.数字信号处理——理论、算法与实现[M].北京:清华大学出版社,1997.
[52] 俞卞章.数字信号处理[M].西安:西北工业大学出版社,2002.256-266.
[53] 李建明,朱康.高压电气设备实验方法[M].北京:中国电力出版社,2001.
[54] A.V奥本海姆等著,刘数堂译。信号与系统 西安交通大学出版社,1985.
[55] A/D器件一览表[EB/OL].http://www.cetinet.com/t_article/list.asp?indexid=432.
[56] 曹庆文,张东海,李宁.12位双路同时转换A/D转换器AD7862及其应用[J].山西电子技术,2003,3:17~19.
[57] Dishan H. Phase error in fast Fourier transform analysis[J]. Mech Syst Signal Process, 1995, 9(2): 113-118.
[58] Ignacio Santamar`a-Caballero, Carlos J, Pantale`on-Prieto, et al. Improved Procedures for Estimating Amplitudes and Phases of Harmonics with Application to Vibration Analysis[J]. IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT, 1998, 47(1): 209~214.
[59] Alessandro Ferrero, Roberto Ottoboni. High-accuracy fourier analysis based on synchronous sampling techniques[J]. IEEE Trans, On instrumentation and measurement, 1992, 41(6): 780~785.
[60] 胡勇,王呈方.一种新的鉴相倍频电路[J].电测与仪表,1998,35(396):38~40.
[61] 余健明,同向前.基于鉴相原理的瞬时谐波电流检测方法研究[J].西安理工大学学报,1998,15(1):61~63.
[62] 北京精电蓬远显示技术有限公司.COG--VP12864液晶显示模块使用手册[M].2002.
[63] 陈勇,黄石红.液晶显示模块与单片机接口技术[J].南京林业大学学报(自然科学版),2002,26(5):24~26.
[64] 程佩青.数字信号处理教程[M].北京:清华大学出版社,2001.
[65] 丁磊,潘贞存,丛伟.基于MATLAB信号处理工具箱的数字滤波器设计与仿真[J].继电器,2003,31(9):49~51.
[66] 闫胜利.FIR滤波器原理及设计方法[J].长春工程学院学报(自然科学版),2003,4(1):63~65.
[67] 廖瑞金,王忠毅,孙才新,等.电气设备介质损耗监测的谐波分析法及其特性[J].重庆大学学报(自然科学版),1999,22(3):67~71.
[68] 李新福,刘教民,崔玉龙,等.电器检测的谐波分析算法[J].河北工业大学学报,2003,32(5):23~26.
[69] 韩捷,张瑞林.旋转机械故障机理及诊断技术[M].北京:机械工业出版社,1997.32-34.
[70] 肖宛昂,嵌入式系统中FFT算法研究[J/OL].http://www.dpj.com.cn/first.htm,2000-7-25.
[71] 毛俊,张学智.快速傅里叶变换算法的比较[J].西安工业学院学报,2002,22(2):106-112.
[72] 曹钧.提高快速傅里叶变换算法效率的方法[J].微电子学与计算机,1994,5:13~15.
[73] 应启珩,冯一云,窦维蓓.离散时间信号分析和处理[M].北京:清华大学出版社,2001.
[74] Benetazzo L, Narduzzi C, Offelli C. Leakage noise reduction in digital signal processing[C]. Proc.1st symp, 1986. 131-136.
[75] 王楠,律方成,梁英.基于修正理想采样频率的谐波分析法在介损在线测量中的应用[J].电测与仪表,2003,40(451):12~15.
[76] 尚勇,杨敏中,王晓蓉,等.谐波分析法介质损耗因数测量的误差分析[J].电工技术学报,2002,17(3):67~72.
[77] Jain V K, Collins W L, David D C. High-accuracy analog measurement via interpolated FFT[J]. IEEE Trans on Instrument and measurement, 1979, 28(2): 113~122.
[78] Grandke T. Interpolation algorithms for discrete fourier transforms of weighed signals[J]. IEEE trans IM, 1983, 32: 350~355.
[79] 张伏生,耿中行,葛耀中.电力系统谐波分析的高精度FFT算法[J].中国电机工程学报,1999,19(3):63~66.
[80] Andria G, Savino M, Trotta A. Windows and interpolation algorithms to improve electrical measurement accuracy[J]. IEEE Trans IM, 1989, 38: 856~863.
[81] Thomas G. Interpolation algorithms for discrete fourier transform of weighed signals[J]. IEEE Trans on Power Delivery, 2001, 16(2): 160~164.
[82] 祁才君,陈隆道,王小海.应用插值FFT算法精确估计电网谐波参数[J].浙江大学学报,2003,37(1):112~116.
[83] 毛莜,肖雁鸿,龚理专.FFT应用于谐波测量中频谱泄漏的分析与处理[J].电工技术杂志,200,2:3~7.
[84] Offelli C, Petri D. Interpolation techniques for real-time multifrequency waveform analysis[J]. IEEE Trans. Instrument. Means, 1990, 39: 106-111.
[85] 谢明,丁康.频谱分析的校正方法[J].振动工程学报,1994,7(2):172~179.
[86] 谈克雄,李福祺,张会平,等.提高电容型设备介损监测装置性能的意见[J].高电压技术,2002,28(12):21~25.
[87] 刘海峰,阎春雨,董金哲.在线监测介质损耗因数的影响因素与结果分析[J].华北电力技术,2002,12:25~27
[88] 朱德恒,严璋.高电压绝缘[M].北京:清华大学出版社,1992.
[89] 于虹.电磁兼容中差模与共模干扰及抑制技术[J].计量技术,1997,2:25~27.
[90] 姚刚,贺家李,王钢,等.电力系统自动化设备的电磁兼容技术[J].电力系统及其自动化学报,2002,12(4):52~57.
[91] 罗兵,孙才新,顾乐观.局部放电在线检测中的电磁干扰及抑制方法[J].高压电器,1995,3:44~47.
[92] 曾斌.现场电测仪表的干扰分析及防护[J].仪器仪表用户,2002,9(5):39~41.
[93] 李国金,任晓奎,赵丹.单片机应用系统的抗干扰技术[J].现代电子技术,2003,15:67~69.
[94] 黄晓玲,吴亚坤.抗干扰设计与实现[J].辽宁大学学报自然科学版,2001,28(2):123~126.
[95] 肖毅,肖明.单片机抗干扰技术及应用[J].电子产品世界,2002,1:54~56.
[96] 栗三喜,丁书文.变电站综合自动化设备的抗干扰技术[J].东北电力技术,2003,3:32~34.
[97] 徐瑞荣.印制版电路抗干扰设计[J].船舶电子对抗,2001(4):34~35.
[98] 赵明,刘海江.单片机应用系统中的抗干扰措施[J].仪表技术,2002,6:48~50.
[99] 贺建华,张冠忠.单片机应用系统中的软件抗干扰[J].徐州建筑职业技术学院学报,2001,1(1):62~64.
[100] 孙茂松.单片机在应用中的软件抗干扰技术[J].唐山师范学院学报,2001,23(2):69~71.
[101] 单片机系统软件抗干扰方法[J/OL].http://www.mcufan.com/article/s-kgr.htm..
[102] 张正喜.单片机应用系统的抗干扰软件设计[J].计算机测量与控制,2002,10(11):746~749.
[103] 杨华舒,楮福涛.单片计算机系统抗干扰的软件途径[J].电子技术应用,2001(3):20~22.
[2] 王秉仁,葛祥.变电站绝缘在线监测系统[J].电站系统工程,2002,18(1):57~59.
[3] 赵玉林,周启龙.高电压技术[M].北京:机械工业出版社,1997.42-47.
[4] 刘涤尘.电气工程基础[M].武汉理工大学出版社,2002.382-390.
[5] 王乃庆.绝缘在线监测技术的实用性、经济性和可靠性[J].电网技术,1995,19(11):54~56.
[6] 陈化刚.电气设备预防性试验方法[M].北京:水利电力出版社,1994.
[7] 东俊禄,吴旭涛,严南征,等.电容型设备介质损耗带电测试可行性研究[J].西北电力技术,2002,4:31~33.
[8] 王楠,律方成.基于小波变换的介损在线监测数据趋势提取[J].高电压技术,2003,29(3):31~33.
[9] 郭碧红,杨晓洪.我国电力设备在线监测技术的开发应用状况分析[J].电网技术,1999,23(8):65~68.
[10] 林建龙,邓敏,林力辉.高压绝缘设备在线监测系统[J].电网技术,2002,26(1):86~88.
[11] 戴昌彬,洪贞贤.电容型试品介质损耗因数变化的原因与分析[J].变压器,2002,39(9):38~41.
[12] 张泽华.电容型设备介损的带电测试对比分析[J].高电压技术,2001,27(104):83~84.
[13] Zhang Guyin. Calculation and Analysis of Effectiveness of Measuring Parameters during On-line Diagnosing Capacitive-type Insulation[C]. Second Sino-Japanese Conference on Electric Insulation Diagnosis, Shanghai, china, 1992. 129—132.
[14] Wang Jinhan. On-line Measurement of C_x and Tan δ on the Type of Capacitive Electric Equipment[J]. Proceeding of 1994 International Joint Conference, Osaka, Japan, 1994. 447—450.
[15] 朱德恒,严璋.高电压绝缘[M].北京:清华大学出版社,1992.262-263.
[16] 严璋.电气绝缘在线检测技术[M].北京:水利电力出版社,1995.
[17] 陈化刚.电气设备预防性试验方法[M].北京:水利电力出版社,1994.
[18] 周武仲.电力设备维修诊断玉预防性试验[M].北京:中国电力出版社,2002.
[19] 王卫周,吴集光,张菊鹏,等.介质损耗因数的自动数字测量系统[J].电子技术应用,2001,2:34~35.
[20] Rabiner L R, GoldB. Theory and Application of Digital Signal Processing[M]. Prentice-Hall, Inc., Englewood Cliffs,N.J., 1975. 53-140.
[21] 林国庆,陈桂龙.介质损耗数字化测量方法研究[J].计算机测量与控制,2002,10(4):217~219.
[22] Ding pinnan, Zhao Erdong. Digital Measurement Technique of Dielectric Loss Angle
Tangent[C]. Second Sino-Japanese on Electric Insulation Diagnosis, Shanghai, China, 1992. 133—135.
[23] Nitaigour, Premchand, Maholik. A Digital Meter for Measuring Dissipation Factor[C]. Proceedings Of the 5th International Conference on Properties and Applications of Dielectric Materials, Seoul, Korea, 1997. 1129—1131.
[24] Guan Genzhi, He Jingliang, Chen pengyun, et al. A Study on the On-line Monitoring and Measuring System for Electric Equipment Insulation in HV Substations[C]. Proceeding of 1994 International Joint Conference, Osaka, Japan, 1994. 287—290.
[25] 曹宇亚,申忠如,任稳柱.介质损耗带电检测数字化处理方法的研究[J].高压电器,2000,3:17~19.
[26] 吕延锋,钟连宏,王建华.电气设备绝缘介质损耗测量方法的研究[J].高电压技术,2001,26(5):38~42.
[27] Mahmud SM. Error Analysis of Digital Phase Measurement of Distorted Waves[J]. IEEE Tans I&M, 1989, 38(1): 6~8.
[28] Allan D M, Boyd K J, Hinde D D. A Continuous Insulation Monitor for High Voltage Transformer Bushings[C]. 7th ISH, German, 1991. 119-122.
[29] 金之俭,肖登明,王耀德.绝缘介质损耗角的数字化测量研究[J].高电压技术,1999,25:49~50.
[30] 蔡国雄,甄为红,杨晓洪,等.测量介质损耗的数字化过零点电压比较法[J].电网技术,2002,26(7):15~18.
[31] Cai Guoxiong. The On-line Dielectric Loss Measurement by Voltage Comparator Method[C]. Proceeding of 1994 International Joint Conference, Osaka, Japan, 1994. 127—130.
[32] 赵秀山,谈克雄,朱德恒,等.介质损耗角的数字化测量[J].清华大学学报,2001,36(9):51~56.
[33] 夏胜国,文远芳.高电压绝缘的Tan δ数字测量方法[J].高压电器,2000,2:38-41.
[34] 王楠,律方成,李艳涛,等.影响介损在线检测准确性的因素分析与探讨[J].电工技术杂志,2003,1:43~45.
[35] 尚勇,杨敏中,王晓蓉,等.谐波分析法介质损耗因数测量的误差分析[J].电工技术学,2002,17(3):67~71.
[36] Allan D M, Blundell M S, Boyd K J, et al. New Insulation Diagnostic and Monitoring Techniques for In-Service HV Apparatus[C]. Proceeding of the 3th International Conference on Properties and Applications of Dielectric Materials, Japan, 1991. 448—451.
[37] Allan D M, Blundell M S, Boyd K J, et al. New Techniques for Monitoring the Insulation Quality of In-service HV Apparatus[J]. IEEE Trans. On Electrical Insulation, 1992, 27(3): 578~585.
[38] Vujovic P, Fricker R P. Development of an on-line continuous Tan δ monitoring system[C]. Conference Record of the 1994 IEEE international symposium on electrical
insulation, ittsburgh USA, 1994. 50-53.
[39] Fricker R K. Monitoring HV Insulation Integrity On-line[J]. Transmission & Distribution World, 1996, 26~37.
[40] 黄新红.Tan δ在线检测技术的研究高压电容型设备[D].西安:西安交通大学1997.
[41] 何循来.高性能八位单片机AT89C5l[J].半导体技术,1997,4:61~63.
[42] 黄本雄,黄沛然,李姣军.高电压设备绝缘在线监测电流传感器的研究[J].华中理工大学学报,1996,24(5):1~2.
[43] 贾逸梅,粟福珩,刘军.一种新型高压电气设备在线绝缘监测系统[J].现代电力,2001,18(2):50~54.
[44] 绝缘在线监测的耳目[EB/OL].http://www.hamsss.com/index.htm.
[45] 中国计量科学研究院.Nonlinear-NS型系列泄漏电流传感器[EB/OL].http://www.Nature.ac.cn/xldlchgq.html.
[46] 西南自动化研究所.WB系列电量隔离传感器简明手册[M].1998.
[47] WB交流电量隔离传感器/变送器[EB/OL].http://www.honeywell-sensor.com.cn/prodinfo/Sensor current/datasheet/close loop curren t csn.pdf.
[48] 一种实用的线性隔离检测电路[EB/OL].http://www.china-power.net/dzkw/00-11/15.htm.
[49] 冯矞云.应启珩,陆延丰,等.模拟和数字滤波器的设计与实现[M].北京:人民邮电出版社,1985.
[50] 童诗白.模拟电子技术基础[M].北京:高等教育出版社,1998.
[51] 胡广书.数字信号处理——理论、算法与实现[M].北京:清华大学出版社,1997.
[52] 俞卞章.数字信号处理[M].西安:西北工业大学出版社,2002.256-266.
[53] 李建明,朱康.高压电气设备实验方法[M].北京:中国电力出版社,2001.
[54] A.V奥本海姆等著,刘数堂译。信号与系统 西安交通大学出版社,1985.
[55] A/D器件一览表[EB/OL].http://www.cetinet.com/t_article/list.asp?indexid=432.
[56] 曹庆文,张东海,李宁.12位双路同时转换A/D转换器AD7862及其应用[J].山西电子技术,2003,3:17~19.
[57] Dishan H. Phase error in fast Fourier transform analysis[J]. Mech Syst Signal Process, 1995, 9(2): 113-118.
[58] Ignacio Santamar`a-Caballero, Carlos J, Pantale`on-Prieto, et al. Improved Procedures for Estimating Amplitudes and Phases of Harmonics with Application to Vibration Analysis[J]. IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT, 1998, 47(1): 209~214.
[59] Alessandro Ferrero, Roberto Ottoboni. High-accuracy fourier analysis based on synchronous sampling techniques[J]. IEEE Trans, On instrumentation and measurement, 1992, 41(6): 780~785.
[60] 胡勇,王呈方.一种新的鉴相倍频电路[J].电测与仪表,1998,35(396):38~40.
[61] 余健明,同向前.基于鉴相原理的瞬时谐波电流检测方法研究[J].西安理工大学学报,1998,15(1):61~63.
[62] 北京精电蓬远显示技术有限公司.COG--VP12864液晶显示模块使用手册[M].2002.
[63] 陈勇,黄石红.液晶显示模块与单片机接口技术[J].南京林业大学学报(自然科学版),2002,26(5):24~26.
[64] 程佩青.数字信号处理教程[M].北京:清华大学出版社,2001.
[65] 丁磊,潘贞存,丛伟.基于MATLAB信号处理工具箱的数字滤波器设计与仿真[J].继电器,2003,31(9):49~51.
[66] 闫胜利.FIR滤波器原理及设计方法[J].长春工程学院学报(自然科学版),2003,4(1):63~65.
[67] 廖瑞金,王忠毅,孙才新,等.电气设备介质损耗监测的谐波分析法及其特性[J].重庆大学学报(自然科学版),1999,22(3):67~71.
[68] 李新福,刘教民,崔玉龙,等.电器检测的谐波分析算法[J].河北工业大学学报,2003,32(5):23~26.
[69] 韩捷,张瑞林.旋转机械故障机理及诊断技术[M].北京:机械工业出版社,1997.32-34.
[70] 肖宛昂,嵌入式系统中FFT算法研究[J/OL].http://www.dpj.com.cn/first.htm,2000-7-25.
[71] 毛俊,张学智.快速傅里叶变换算法的比较[J].西安工业学院学报,2002,22(2):106-112.
[72] 曹钧.提高快速傅里叶变换算法效率的方法[J].微电子学与计算机,1994,5:13~15.
[73] 应启珩,冯一云,窦维蓓.离散时间信号分析和处理[M].北京:清华大学出版社,2001.
[74] Benetazzo L, Narduzzi C, Offelli C. Leakage noise reduction in digital signal processing[C]. Proc.1st symp, 1986. 131-136.
[75] 王楠,律方成,梁英.基于修正理想采样频率的谐波分析法在介损在线测量中的应用[J].电测与仪表,2003,40(451):12~15.
[76] 尚勇,杨敏中,王晓蓉,等.谐波分析法介质损耗因数测量的误差分析[J].电工技术学报,2002,17(3):67~72.
[77] Jain V K, Collins W L, David D C. High-accuracy analog measurement via interpolated FFT[J]. IEEE Trans on Instrument and measurement, 1979, 28(2): 113~122.
[78] Grandke T. Interpolation algorithms for discrete fourier transforms of weighed signals[J]. IEEE trans IM, 1983, 32: 350~355.
[79] 张伏生,耿中行,葛耀中.电力系统谐波分析的高精度FFT算法[J].中国电机工程学报,1999,19(3):63~66.
[80] Andria G, Savino M, Trotta A. Windows and interpolation algorithms to improve electrical measurement accuracy[J]. IEEE Trans IM, 1989, 38: 856~863.
[81] Thomas G. Interpolation algorithms for discrete fourier transform of weighed signals[J]. IEEE Trans on Power Delivery, 2001, 16(2): 160~164.
[82] 祁才君,陈隆道,王小海.应用插值FFT算法精确估计电网谐波参数[J].浙江大学学报,2003,37(1):112~116.
[83] 毛莜,肖雁鸿,龚理专.FFT应用于谐波测量中频谱泄漏的分析与处理[J].电工技术杂志,200,2:3~7.
[84] Offelli C, Petri D. Interpolation techniques for real-time multifrequency waveform analysis[J]. IEEE Trans. Instrument. Means, 1990, 39: 106-111.
[85] 谢明,丁康.频谱分析的校正方法[J].振动工程学报,1994,7(2):172~179.
[86] 谈克雄,李福祺,张会平,等.提高电容型设备介损监测装置性能的意见[J].高电压技术,2002,28(12):21~25.
[87] 刘海峰,阎春雨,董金哲.在线监测介质损耗因数的影响因素与结果分析[J].华北电力技术,2002,12:25~27
[88] 朱德恒,严璋.高电压绝缘[M].北京:清华大学出版社,1992.
[89] 于虹.电磁兼容中差模与共模干扰及抑制技术[J].计量技术,1997,2:25~27.
[90] 姚刚,贺家李,王钢,等.电力系统自动化设备的电磁兼容技术[J].电力系统及其自动化学报,2002,12(4):52~57.
[91] 罗兵,孙才新,顾乐观.局部放电在线检测中的电磁干扰及抑制方法[J].高压电器,1995,3:44~47.
[92] 曾斌.现场电测仪表的干扰分析及防护[J].仪器仪表用户,2002,9(5):39~41.
[93] 李国金,任晓奎,赵丹.单片机应用系统的抗干扰技术[J].现代电子技术,2003,15:67~69.
[94] 黄晓玲,吴亚坤.抗干扰设计与实现[J].辽宁大学学报自然科学版,2001,28(2):123~126.
[95] 肖毅,肖明.单片机抗干扰技术及应用[J].电子产品世界,2002,1:54~56.
[96] 栗三喜,丁书文.变电站综合自动化设备的抗干扰技术[J].东北电力技术,2003,3:32~34.
[97] 徐瑞荣.印制版电路抗干扰设计[J].船舶电子对抗,2001(4):34~35.
[98] 赵明,刘海江.单片机应用系统中的抗干扰措施[J].仪表技术,2002,6:48~50.
[99] 贺建华,张冠忠.单片机应用系统中的软件抗干扰[J].徐州建筑职业技术学院学报,2001,1(1):62~64.
[100] 孙茂松.单片机在应用中的软件抗干扰技术[J].唐山师范学院学报,2001,23(2):69~71.
[101] 单片机系统软件抗干扰方法[J/OL].http://www.mcufan.com/article/s-kgr.htm..
[102] 张正喜.单片机应用系统的抗干扰软件设计[J].计算机测量与控制,2002,10(11):746~749.
[103] 杨华舒,楮福涛.单片计算机系统抗干扰的软件途径[J].电子技术应用,2001(3):20~22.