供电线路对电能表电量计量误差的研究
|
摘要
本研究以理论计算方法和实验数据为依据,对供电线路对电能表电量计量产生的误差进行比较分析,建议采用计算法来追补损失电量。研究的重点有四个方面:一是电能表电量计量的基本原理,分析了感应式电能表电量计量的基本原理和电子式电能表电量计量的基本原理以及两者的异同点和优缺点。并介绍了目前使用的电能表特点。二是对供电线路对电能表电量计量误差进行了分析,对电压互感器、电流互感器对电量计量产生的误差的原因和解决的方法进行了描述和比较。三是对供电线路对电量计量带来的误差进行了理论分析及追补电量的计算,对实际工作中经常遇见的感应式电能表电压A、B、C三相任意相高压保险丝熔断带来的计量误差、电子式电能表电压A、B、C三相任意相高压保险丝熔断带来的计量误差、电流互感器极性接反带来的计量误差进行了理论分析及追补电量的计算。四是大量的实验研究,理论是要靠实践来证明,本研究以电子式三相三线多功能电能表,在三相电能表校验台上进行模拟现场试验。
实验验证主要分为四个部分:一是被试表(两种电源结构三相三线电能表)基本误差测定。二是被试表断压时在表端子座测得电压(V)。三是失压时电能表的误差测定。四是失压下走字试验。并将利用表误差来补算的有功电量及无功电量(依据补电量计算系数)与正常状态工作下对应的电量进行比较,所得结果相吻合,为供电线路对电量计量带来误差的理论分析及追补电量计算的准确性提供了依据。解决了日常工作中由于各种因数导致电量计量产生误差而需追补电量的问题,达到仲裁计量纠纷的目的。
The theoretical calculation method and experimental data as the basis, the power supply circuit to power measurement error of the produce electric energy meter, this paper analyzes the recommended calculation method to ZhuiBu power loss. The focus of research has four aspects:one is the basic principle of electric power measurement, this paper analyzes the inductive power meter measuring the basic principle and electrical meter measuring power the basic principle and the differences and similarities between both advantages and disadvantages. And introduced the current use of electric energy meter characteristics.2 it is for power supply circuit to power electric energy meter measuring error was analyzed and the voltage transformer, current transformer in one of the cause of the error of measurement produce and the solving methods are described and compared. Three of the power supply lines is to bring power measurement of the error theory analysis and ZhuiBu power calculation and practical work often meet of inductive voltage meter A, B and C three-phase any phase of high pressure fuse fusing bring error, electrical meter measuring voltage A, B, C three-phase any phase high pressure measuring error brought fusing the fuse, current transformer at the polarity of the measurement error brought the theory analysis and ZhuiBu power calculation. Four is a large number of experimental research, the theory is to rely on practice to prove, the electronic three-phase three line multi-function watt-hour meter, three-phase watt-hour meter calibration on the simulation test.
Experiment mainly divided into four parts:one is the temperature was (two power structure three-phase three line watt-hour meter) basic error determination.2 it is the temperature was broken pressure in the table terminal measured a voltage (V). Three is to lose pressure watt-hour meter of the error of measurement. Four is under pressure loss go word test. And will use the table to fill the active error is power and reactive power (basis for calculating power coefficient) and the normal work of the corresponding power compared, the results coincide, for the power supply circuit to bring power measurement error of the theoretical analysis and ZhuiBu power the accuracy of the calculation to provide the basis. Solve the daily work because all kinds of factor lead to power measurement errors of the problem and the need to ZhuiBu power, to the purpose of the dispute arbitration measurement.
实验验证主要分为四个部分:一是被试表(两种电源结构三相三线电能表)基本误差测定。二是被试表断压时在表端子座测得电压(V)。三是失压时电能表的误差测定。四是失压下走字试验。并将利用表误差来补算的有功电量及无功电量(依据补电量计算系数)与正常状态工作下对应的电量进行比较,所得结果相吻合,为供电线路对电量计量带来误差的理论分析及追补电量计算的准确性提供了依据。解决了日常工作中由于各种因数导致电量计量产生误差而需追补电量的问题,达到仲裁计量纠纷的目的。
The theoretical calculation method and experimental data as the basis, the power supply circuit to power measurement error of the produce electric energy meter, this paper analyzes the recommended calculation method to ZhuiBu power loss. The focus of research has four aspects:one is the basic principle of electric power measurement, this paper analyzes the inductive power meter measuring the basic principle and electrical meter measuring power the basic principle and the differences and similarities between both advantages and disadvantages. And introduced the current use of electric energy meter characteristics.2 it is for power supply circuit to power electric energy meter measuring error was analyzed and the voltage transformer, current transformer in one of the cause of the error of measurement produce and the solving methods are described and compared. Three of the power supply lines is to bring power measurement of the error theory analysis and ZhuiBu power calculation and practical work often meet of inductive voltage meter A, B and C three-phase any phase of high pressure fuse fusing bring error, electrical meter measuring voltage A, B, C three-phase any phase high pressure measuring error brought fusing the fuse, current transformer at the polarity of the measurement error brought the theory analysis and ZhuiBu power calculation. Four is a large number of experimental research, the theory is to rely on practice to prove, the electronic three-phase three line multi-function watt-hour meter, three-phase watt-hour meter calibration on the simulation test.
Experiment mainly divided into four parts:one is the temperature was (two power structure three-phase three line watt-hour meter) basic error determination.2 it is the temperature was broken pressure in the table terminal measured a voltage (V). Three is to lose pressure watt-hour meter of the error of measurement. Four is under pressure loss go word test. And will use the table to fill the active error is power and reactive power (basis for calculating power coefficient) and the normal work of the corresponding power compared, the results coincide, for the power supply circuit to bring power measurement error of the theoretical analysis and ZhuiBu power the accuracy of the calculation to provide the basis. Solve the daily work because all kinds of factor lead to power measurement errors of the problem and the need to ZhuiBu power, to the purpose of the dispute arbitration measurement.
引文
[1]楮大华编著.电子式电能表.第1版.北京:中国电力出版社,2009
[2]李文.智能电工仪表特点及应用.中国计量.2007(10):51-52
[3]杨晓西,宋晓林.国内电网关口表运行主要问题分析.环球表计中文版.2005(1):16-18
[4]郑万红.电动系三相三线有功功率表的原理、使用及校验.中国计量.2006(11):67-68
[5]顾定军,陈鸣,陈能塔.三相三线电子式多功能电能表失压追补电量分析.计量技术.2010(11):10-13
[6]程占东,薛巨东.单相机械式电能表检定中常见故障分析与排除.计量与测试技术.2010(9)37卷:55-56
[7]马利人,彭中华.智能电能表中磁保持继电器工况的综合分析.计量技术.2010(2):22-25
[8]李德煌,于彬,刘延广,康广庸.电能表电压线圈的中点与零线断开时计量误差分析.计量技术.2008(10):22-24
[9]叶利,夏水斌,申莉.智能电能表通信协议及功能一致性检测方法的设计.电测与仪表.2010(A08)47卷:19-22
[10]陈晖.单相复费率电能表的原理及功能.中国科技博览.2008(16):33-34
[11]宗建华等编著.智能电能表.第1版.北京:中国电力出版社,2010
[12]张素君,闫雷兵,赵建军.高压电力计量系统CT短路故障分析与检测.计量与测试技术.2010(4)37卷:7-9
[13]翟清昌.新型三相电能表和110kV以上高压电能计量电网测控系统新方案.中国计量.2007(7):49-51
[14]舒华.如何正确选择电能计量装置及安装检查.中国计量.2007(7):55
[15]李博,赵波.对电能表行业标准中功耗试验方法的修改建议.中国计量.2007(10):68-69
[16]叶云燕.新型智能防窃电与计量电表技术及其应用.半导体器件应用.2009(11):45-47
[17]高淑荣,金希柱,郭成云.单相机电脉冲式IC卡电能表的应用及常见故障分析处理.中国计量.2006(11):59
[18]戴伟.电能表现场校验仪使用中应注意的问题.中国计量.2007(1):54-55
[19]李永军,徐晓蓉,肖海红.基于DSP的电能表现场校验仪系统.中国计 量.2010(1):61-63
[20]张瑞占,屈百达.基于ATT7022B三相精确计量智能电能表设计.电子测量技术.2008(9)31卷:150-153 169
[21]窦永强.电能计量装置接线正确性的快速、准确判别方法.中国计量.2010(1):120-121
[22]李静,杨以涵,于文斌、,张国庆,宁伟红.电能计量系统发展综述.电力系统保护与控制.2009(11)37卷:130-134
[23]王立新.探索一种符合法律要求的电能计量模式.中国电业.2010(3):74-77
[24]冯勇军.在35kV及以下配电网中宜用计量箱计量电能.中国计量.2010(3):89-91
[25]王华文,马伟.电能计量装置的综合误差及其减小方法.中国计量.2010(5):98-100
[26]潘志红.电网关口电量追补办法.中国电力.2003(5):34-35
[27]孟庆亮.电厂关口电量追补技术分析.广西电力.2010(3):27-29
[28]王先春,樊希平,彭建英,乔闹生.基于ARM的嵌入式电能计量系统设计.微计算机信息.2009(17)25卷:213-214 245
[29]赵江波.电能计量装置故障接线分析.中国计量.2010(10):112
[30]薛昌波,周飞龙.智能技术在电能计量领域的展望.中国计量.2010(4):31-33
[31]郭立才,彭志炜,范强.电能计量及反窃电方法综述.高压电器.2010(5)46卷:24-26
[32]翟清昌.电能计量技术常见问题解析.智能电网与计量标准.中国计量.2010(4):28-30
[33]刘润军主编.电能计量技术常见问题解析.第1版.北京:中国计量出版社,2006
[34]商福恭编著.电能表接线技巧.第1版.北京:中国电力出版社,2007
[35]刘光辉编著.防窃电措施与案例分析.第1版.北京:机械工业出版社,2009
[36]崔彦彬,孙岩.一种多用户智能型电能表的设计.机械设计与制造.2008(2):9-10
[37]李大鹏,王祁.三相复费率网络化智能电能表的研制.仪器仪表学报.2006(6)27卷:14-16
[38]郑志华.胜利油田电能量采集与线损分析系统的方案研究.中国计量.2010 (6):102-105
[39]陶向东.企业社区电能计量改造中发现的问题.中国计量.2010(3):36-37
[40]刘洪利.智能型复费率数字电能表的设计.上海电力学院学报.2005(3)21卷:242-243252
[41]邢道清编著.电能计量与电能表修校.第1版.北京:机械工业出版社,2009
[42]陈旭阳.电能表接线错误时电能值的更正方法.中国计量.2011(4):115-116
[43]李正强,郑荐中,方杰.标准电能表电能误差数据合理性判定初探.中国计量.2011(2):71-73
[44]李峰.多功能电能表时钟误差的检定.中国计量.2007(10):61-62
[45]王华文,莫伟忠.PDA在电能表现场校验管系统中的应用.中国计量.2010(9):101-102 118
[46]GB 1208-2006.电流互感器
[2]李文.智能电工仪表特点及应用.中国计量.2007(10):51-52
[3]杨晓西,宋晓林.国内电网关口表运行主要问题分析.环球表计中文版.2005(1):16-18
[4]郑万红.电动系三相三线有功功率表的原理、使用及校验.中国计量.2006(11):67-68
[5]顾定军,陈鸣,陈能塔.三相三线电子式多功能电能表失压追补电量分析.计量技术.2010(11):10-13
[6]程占东,薛巨东.单相机械式电能表检定中常见故障分析与排除.计量与测试技术.2010(9)37卷:55-56
[7]马利人,彭中华.智能电能表中磁保持继电器工况的综合分析.计量技术.2010(2):22-25
[8]李德煌,于彬,刘延广,康广庸.电能表电压线圈的中点与零线断开时计量误差分析.计量技术.2008(10):22-24
[9]叶利,夏水斌,申莉.智能电能表通信协议及功能一致性检测方法的设计.电测与仪表.2010(A08)47卷:19-22
[10]陈晖.单相复费率电能表的原理及功能.中国科技博览.2008(16):33-34
[11]宗建华等编著.智能电能表.第1版.北京:中国电力出版社,2010
[12]张素君,闫雷兵,赵建军.高压电力计量系统CT短路故障分析与检测.计量与测试技术.2010(4)37卷:7-9
[13]翟清昌.新型三相电能表和110kV以上高压电能计量电网测控系统新方案.中国计量.2007(7):49-51
[14]舒华.如何正确选择电能计量装置及安装检查.中国计量.2007(7):55
[15]李博,赵波.对电能表行业标准中功耗试验方法的修改建议.中国计量.2007(10):68-69
[16]叶云燕.新型智能防窃电与计量电表技术及其应用.半导体器件应用.2009(11):45-47
[17]高淑荣,金希柱,郭成云.单相机电脉冲式IC卡电能表的应用及常见故障分析处理.中国计量.2006(11):59
[18]戴伟.电能表现场校验仪使用中应注意的问题.中国计量.2007(1):54-55
[19]李永军,徐晓蓉,肖海红.基于DSP的电能表现场校验仪系统.中国计 量.2010(1):61-63
[20]张瑞占,屈百达.基于ATT7022B三相精确计量智能电能表设计.电子测量技术.2008(9)31卷:150-153 169
[21]窦永强.电能计量装置接线正确性的快速、准确判别方法.中国计量.2010(1):120-121
[22]李静,杨以涵,于文斌、,张国庆,宁伟红.电能计量系统发展综述.电力系统保护与控制.2009(11)37卷:130-134
[23]王立新.探索一种符合法律要求的电能计量模式.中国电业.2010(3):74-77
[24]冯勇军.在35kV及以下配电网中宜用计量箱计量电能.中国计量.2010(3):89-91
[25]王华文,马伟.电能计量装置的综合误差及其减小方法.中国计量.2010(5):98-100
[26]潘志红.电网关口电量追补办法.中国电力.2003(5):34-35
[27]孟庆亮.电厂关口电量追补技术分析.广西电力.2010(3):27-29
[28]王先春,樊希平,彭建英,乔闹生.基于ARM的嵌入式电能计量系统设计.微计算机信息.2009(17)25卷:213-214 245
[29]赵江波.电能计量装置故障接线分析.中国计量.2010(10):112
[30]薛昌波,周飞龙.智能技术在电能计量领域的展望.中国计量.2010(4):31-33
[31]郭立才,彭志炜,范强.电能计量及反窃电方法综述.高压电器.2010(5)46卷:24-26
[32]翟清昌.电能计量技术常见问题解析.智能电网与计量标准.中国计量.2010(4):28-30
[33]刘润军主编.电能计量技术常见问题解析.第1版.北京:中国计量出版社,2006
[34]商福恭编著.电能表接线技巧.第1版.北京:中国电力出版社,2007
[35]刘光辉编著.防窃电措施与案例分析.第1版.北京:机械工业出版社,2009
[36]崔彦彬,孙岩.一种多用户智能型电能表的设计.机械设计与制造.2008(2):9-10
[37]李大鹏,王祁.三相复费率网络化智能电能表的研制.仪器仪表学报.2006(6)27卷:14-16
[38]郑志华.胜利油田电能量采集与线损分析系统的方案研究.中国计量.2010 (6):102-105
[39]陶向东.企业社区电能计量改造中发现的问题.中国计量.2010(3):36-37
[40]刘洪利.智能型复费率数字电能表的设计.上海电力学院学报.2005(3)21卷:242-243252
[41]邢道清编著.电能计量与电能表修校.第1版.北京:机械工业出版社,2009
[42]陈旭阳.电能表接线错误时电能值的更正方法.中国计量.2011(4):115-116
[43]李正强,郑荐中,方杰.标准电能表电能误差数据合理性判定初探.中国计量.2011(2):71-73
[44]李峰.多功能电能表时钟误差的检定.中国计量.2007(10):61-62
[45]王华文,莫伟忠.PDA在电能表现场校验管系统中的应用.中国计量.2010(9):101-102 118
[46]GB 1208-2006.电流互感器