1、PDF外文:http:/ A LabVIEW Based Instrument Current Transformer Calibrator XinAi Hal BaoY.H. Song 1) NorthChinaElectricPowerUniversity, Beijing, China 107206 2)BrunelUniversity.UK ABSTRACT The Virtual Instrument (VI) mainly refers to build all kinds of instruments by softw
2、are such as LabVIEW,which likes a real instrument buildin a computer. Its' main characteristicsare flexibility, multi-functions, multiple uses for one PC computer, giving high performance, and is less costly. In this paper, the VI technology is applied to the test and measurement of instrument c
3、urrent transformer (TA). By using the LabVIEW, the TA accuracy calibrator was developed. This virtual T.4 calibrator can automatically measure the accuracy of T.4 and can indicate the ratio error and phase error curves. The tests and calibration for the TA show that the virtual TA calibrator can be
4、used in place of the traditional calibrator and is much better than the traditional one. Keywords: Instrument current transformer (TA), TA calibrator, Virtual Instruments, LabVIEW. I. INTRODUCTION Since 1992 the VXIbus Rev.1.4standard was established by the United States and LabVIEW was presented by
5、 the National Instruments co.(Nl), the Virtual Instrument (VI) have lain the foundation for its commercial use. The main characteristic of Virtual Instrument is that it makes instruments by software. Most of the traditional instrument can be developed by VI. The VI is a real instrument made by the p
6、ersonal computer. The Instrument current transformer (TA) is widely used in all kinds of current measurement and it has the functions of protection, isolation and extending the measuring range. With the rapid development of computer measurement and control technology, and with the sequent emergence
7、of current transformer and transducer, there is an increasing number of current transformers with high accuracy and low secondary current. The standard TA secondary current is usually 1A or 5A: some non-standard TA secondary current may be 0 1A or lower. Although we have the technique to make this k
8、ind of calibrator by means of hardware such as single chip computer and electronic circuit, DSP and so on, it will cost too much money for these no-standard calibrator and will take too much time and the calibrator made by these hardware mill not be satisfactory in both function and practicality for
9、 designing all kinds of new TA. The calibrator that adopts VI technology not only can meet the requirements of the traditional one but also can satisfy customers with such advantages as multi-functions, convenience, and high ratio between performance and cost. The experiment results indi
10、cate that the virtual calibrator can provide excellent condition for TA measurement and design. The VI technology and personal computer must be widely used in the area of calibration on instrument transformer. . THE WORKING PRINCIPLE OF TA CALIBRATOR The error of TA includes ratio error and ph
11、ase error. The measuring of the error of TA or the calibration of the accuracy of TA usually applies differential measuring method. The method needs a standard TA except the measured TA and a TA calibrator. There is the same turn ratio between the standard and measured T4 and the standard TA's a
12、ccuracy should be 2 levels higher than the measured one. The calibrator function lies in forming comparison circuits, measuring, and showing the error at all range. The comparison circuit, also referred to the difference measuring principle circuit, is showed in Fig. 1. By measuring the voltage on I
13、, and Rd, calculate the corresponding current. Then the calibrator can indicate the error. When a TA has the same turn ratio between the primary and secondary winding, the self-comparison circuit could be used and is shown in Fig.2. In the figures, TA0 and TAX are standard and TA being measure
14、d respectively. Np and Ns are primary and secondary winding turns. ip and io, id, i, are primary currentsecondary standard current, secondary error current, secondary current of TA being measured respectively. Ro and R,R, are secondary winding's resistance of standard TA, error currentdete
15、cting resistance, burden resistance ofTA being measured respectively. To and K, Tb. T, are voltage sampling points which can calculate the current In this paper, only voltage between K and T, voltage between Tb and T, are being measured and they represent the voltage on R, and R, respectively.
16、;In general, the TA calibrator's principle of the sample resistance should be: 1) it can not affect the accuracy of the comparison circuit. In the ideal condition R, and Rd should be 0, but it can not be sampled. So there must be sample resistance, in this paper, R, as shown in Fig,
17、is used; 1) the magnitude of the sample resistance should make the sampled standard current anderror current in pro rata and should not have too much difference. The sampled resistance is set by experiment: R, is the secondary standard current sampling resistance andcan be 0.1-0.5
18、0, R, is the error current sampling resistance and canbe, R, is the burden resistance and it depends on the TA being measured. E$ sampling the voltage uo and U, on R, and R, respectively, the ratio error and phase error are showed on the LED through some process and calculations. According to
19、the TA error's phase diagram, when io is maximum, the value of id is the ratio error; when io changes from negative to positive and equals to 0, the value of id is the phase error. For the same principle, the relationship is equal to the voltage signal U, and ud. showed in Fig.3. a and b is represent the ratio error and phase error separately. the TA's real ratio error C and phase error 6 can be found out through proper calculation,
