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

Faifer, Marco; Ottoboni, R.; Toscani, Sergio; Cherbaucich, C.; Mazza, Paolo

doi:10.1109/tim.2014.2376113

Cited by 33 publications

(12 citation statements)

References 21 publications

(25 reference statements)

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“…A two second time window (hence 100 fundamental periods) and 100 kHz sampling rate have been employed. The estimated FRF can be used to pre-filter the spectrum of the desired excitation signal, thus obtaining the signal v g to be applied at the input of the power amplifier [21], [22].…”

Section: Resultsmentioning

confidence: 99%

Overcoming Frequency Response Measurements of Voltage Transformers: An Approach Based on Quasi-Sinusoidal Volterra Models

Faifer

Laurano

Ottoboni

et al. 2019

IEEE Trans. Instrum. Meas.

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The most recent IEC standards about voltage transformers warn about nonlinearity, which may have significantly impact on the harmonic measurement performance. However, there is a lack of scientific literature about this topic: usually their characterization consists of frequency response measurements, which are clearly not able to capture the nonlinear behavior.In this paper, an innovative approach based on simplified frequency domain polynomial models developed by the authors is proposed. The method is applied to two different medium voltage inductive transformers. Models are identified and validated with a large set of realistic primary waveforms injected by a proper setup. Experimental results confirm the remarkable accuracy of the proposed models especially for low-order harmonics, which are the most affected by nonlinearity.

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Section: Resultsmentioning

confidence: 99%

Overcoming Frequency Response Measurements of Voltage Transformers: An Approach Based on Quasi-Sinusoidal Volterra Models

Faifer

Laurano

Ottoboni

et al. 2019

IEEE Trans. Instrum. Meas.

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“…Its architecture resembled that of a voltage generator [7], [8] previously developed by the authors for the testing of medium voltage transducers; the architecture is shown in Fig. 7, while its block diagram is reported in Fig.…”

Section: Methodsmentioning

confidence: 99%

Simple skin effect compensation in cylindrical shunts

Faifer

Laurano

Ottoboni

et al. 2016

2016 IEEE International Workshop on Applied Measurements for Power Systems (AMPS)

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This paper proposes a new design solution for high-current shunt resistors aiming at optimizing the frequency response in a specified frequency range. It is based on a solid cylindrical shunt, whose sensing circuit runs through a straight hole drilled in the shunt itself. Compared to other solutions proposed in the literature, typically based on coaxial or cage configurations, this approach allows a more compact size, a simple mathematical modeling of the current distribution due to skin effect (therefore less complex mathematical solution of the optimization problem) and a cost-effective manufacturing process. Experimental results obtained from a shunt prototype are reported, which confirm the validity of the proposed approach

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“…The fifth order simplified Volterra model recalled in the previous section has been used to represent the behavior of a CVT under test (TUT) having 0.5 accuracy class, 200V/100V voltage ratio and 20 VA rated burden. Its primary winding has been connected to an arbitrary voltage generator, similar to that described in [28], able to generate the proper voltage signals required by the tests. Primary and secondary winding voltages of the TUT has been collected by using two highaccuracy resistive dividers.…”

Section: Experimental Validation Of the Proposed Modelmentioning

confidence: 99%

On-line fault detection technique for voltage transformers

et al. 2017

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Conventional voltage transformers (CVTs) are still widely used as transducers in power networks, thanks to their high reliability, insulation capability, low drift over time and temperature. Their rugged construction is very often used as justification for skipping periodical tests and calibrations, that require putting them off-line, thus avoiding a time-consuming and expensive procedure. For this reason, in the last years, a growing interest has been addressed towards the study of online diagnostic and calibration procedures. The typical approach is based on the frequency response analysis that permits, under sinusoidal excitation, to detect possible deterioration of the behavior of CVT. Anyway, the real interest is to check the CVT fleet already installed and operating on the grid without requiring their disconnection from the grid. As well known, distribution grid voltage features a non negligible harmonic distortion, which may allow the online evaluation of the frequency response of the transformer, by simply connecting a reference transducer. Unfortunately, being the harmonics much lower than the fundamental, this approach cannot be employed in a straightforward way because of the nonlinear behavior of the CVT. This paper proposes an innovative condition monitoring technique of CVTs based on a simplified Volterra model. This opens the way to a new approach to the on-site characterization of CVTs, exploiting the actual voltage of the grid and thus not requiring its disconnection

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

Cited by 33 publications

References 21 publications

Overcoming Frequency Response Measurements of Voltage Transformers: An Approach Based on Quasi-Sinusoidal Volterra Models

Overcoming Frequency Response Measurements of Voltage Transformers: An Approach Based on Quasi-Sinusoidal Volterra Models

Simple skin effect compensation in cylindrical shunts

On-line fault detection technique for voltage transformers

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