Characterization of an arbitrary medium voltage signal generator

IEEE Trans. Instrum. Meas.

Ottoboni

Toscani

et al. 2015

Self Cite

Nowadays, voltage transducers in medium-voltage (MV) distribution networks operate in nonsinusoidal conditions while their calibration is still based on simple sine-wave tests. A more significant characterization could be achieved using complex multitone signals. However, this requires an MV generator able to apply arbitrary voltage waveforms to the transducer under test. The authors have recently proposed a simple MV signal generator that can be effectively employed for this purpose. In this paper, the performance of this MV generator has been carefully analyzed. A characterization procedure based on multisine excitation has been proposed and tested. In particular, the main causes of uncertainty have been identified and their impact on the accuracy of the generated voltage evaluated. The analysis considers both linear and nonlinear effects, such as harmonic distortion and hysteresis

mentioning

confidence: 99%

Metrological Characterization of a Signal Generator for the Testing of Medium-Voltage Measurement Transducers

IEEE Trans. Instrum. Meas.

Ottoboni

Toscani

et al. 2015

Self Cite

A simple method for the THD improvement of a MV arbitrary waveform generators

Lei

2015 IEEE International Instrumentation and Measurement Technology Conference (I2MTC) Proceedings

Ottoboni

et al. 2015

The development of an arbitrary MV generator (AMVG) is a quite complex task. The level of voltage amplitude requires a careful analysis of any possible solutions at the level of its design, by finding the best tradeoff between performance and cost. In this perspective, a very attractive solution is represented by the way followed by the authors, in which the cost of the AMVG has been kept low thanks to a simple architecture based on few commercial devices. The performances have been increased by means of suitable pre-processing of the input signal. This approach has been yet applied with the aim to extend the generator bandwidth. In this paper the same approach has been applied also to the compensation of the non-linear effect mainly introduced by the step-up transformer used inside the AMVG. The method requires a two-step procedure: first of all a sinusoidal signal is applied to the input of the AMVG and the corresponding output signal is acquired and its spectrum computed. A new input signal able to produce the partial compensation of the unwanted harmonics introduced by the non-linearity of the system is then synthetized. Despite its simplicity and the adoption of a simple modeling of the system, the experimental results prove that it is possible to reduce about three times the THD of the system

Behavior of voltage transformers under distorted conditions

Lei

Cristaldi

2016 IEEE International Instrumentation and Measurement Technology Conference Proceedings

et al. 2016

Nowadays, the presence of nonlinear devices cannot be neglected either for their growing numbers or for their effect on the distribution network. In particular, these devices will produce relevant harmonics, which can cause problems such as increase of losses, over-heating in the power transformer malfunction of the circuit switch and, generally, an untimely aging process of connected devices. As a matter of fact, the presence of harmonics is a power quality issue and this distortion phenomena needs to be strictly monitored. The voltage transformer (VT) is the most popular transducer in the power grid due to its robustness and low cost. The frequency response of these transducers is usually characterized by sweep sine test, which can assure their performance under sinusoidal condition, but not under distortion condition. Based on the standard EN 50160, a new characterization method is proposed in this paper, in order to test the VTs under distortion condition. Several VTs with different rated values have been tested. As a direct consequence, it will be shown that, in working conditions similar to the real ones, the use of VT for the measurement of power quality (PQ) index can lead to wrong interpretations and decisions