Armand van Deursen scite author profile

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Methodology and accuracy for non‐invasive detection of switching transient overvoltages from compensation coils connected to power transformers

Wouters

Deursen

Vermeer

2020

IET Science, Measurement & Technology

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Transient voltages from (dis)connecting compensation coils near high voltage transformers are studied. Non-invasive sensors are needed in order to exclude any influence by the measurement equipment on the overvoltage magnitude. This study describes results from open-air capacitive sensors as part of a differentiating/integrating measurement system. Its bandwidth (up to 10 MHz) allows to record large detail in the switching events. However, the coupling strengths and the cross-couplings inherent to the use of air capacitive sensors need to be determined. Calibration based on symmetric phase voltages during normal operation supplies part of the information. Three methods are compared to supplement this knowledge for establishing the complete coupling matrix between phase conductors and sensors. One method employs estimates from the system configuration, in particular, its symmetry. The other techniques extract information from fast transient events within the responses for both switching on and off. The decoupled waveforms from different methodologies align within their confidence bounds and predict the maximum overvoltage magnitudes within an accuracy of 5% when employing information from the fast transients. Based on measurements performed on two compensation coils, both tested three times, larger overvoltages occurred during energisation compared to de-energisation with maximum amplitude exceeding three per unit. (a) The sensor signals, waveforms after decoupling based on (b) Symmetry, (c) Energisation, (d) De-energisation. The arrows indicate instances where the crosscoupled oscillation from phases 1 and 3 start dominating the (faster) oscillation in the signal representing the interrupted phase 2 IET Sci. Meas. Technol.

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Impact of corrosion on the reliability of low voltage cables with aluminium conductors

Deursen

Kruizinga

Wouters

et al. 2017

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Influence of Temperature on Wave Propagation in Low-Voltage Distribution Cables

Deursen

Wouters

Steennis

2021

IEEE Trans. Dielect. Electr. Insul.

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