Low Power Electronic Voltage Transformer Design and Construction

Year 2023, Volume: 13 Issue: 2, 948 - 959, 01.06.2023

Yusuf Kılınç Ali Fuat Boz

https://doi.org/10.21597/jist.1176380

Abstract

The use of advanced low-power sensing technologies instead of traditional solutions used in the distribution, measurement and control of the power grid has introduced core instrument transformers due to their physical limitations and other reasons. This situation has also brought about the design of low-power voltage transformers. As can be understood from here, analogue measurement and control systems used in power centres are approaching the end of their useful life. This substations need digital automation solutions and new technologies for more efficient performance. Since no iron core is used in the low-power electronic voltage transformer structure, it is robust against network disturbances such as ferroresonance and ferroresonance formation is not encountered. In this study, a low-power electronic voltage transformer is designed and performed experiments are presented. The most essential feature expected in a voltage sensor is that the conversion rate is precise and unchanging. For this reason, the temperature coefficient and leakage capacitance values of the voltage sensor have been designed to have the lowest margin of error. Performance tests were applied to the voltage sensor using mains frequency endurance, partial discharge, accuracy class, linearity and temperature distribution tests. The results of the performance tests show that it has been successfully applied for the design of a precision voltage sensor with an accuracy class conforming to the IEC 61689-11 standard.

Keywords

Voltage sensor, resistive, transformer, IEC 61689-11

References

• Ghaderi, A., Mingotti, A., Peretto, L., & Tinarelli, R. (2020). Low-Power Voltage Transformer Smart Frequency Modeling and Output Prediction up to 2.5 kHz, Using Sinc-Response Approach. Sensors, 20(17), 4889.
• IEC 61000-4-7, International Standard, EMC - Testing and Measurement Techniques- General guide on harmonics and interharmonics measurements andinstrumentation, for power supply systems and equipment connected thereto,Edition 2.1 2009-10
• IEC 60044-7, International Standard, Instrument Transformers – Electronic Voltage Transformers, First Edition 1999-12
• IEC 61869-6: 2016. (2016). Instrument Transformers—Part 6: Additional General Requirements for Low-Power Instrument Transformers.
• International Electrotechnical Commission. (2011). IEC 61869-3 Additional Requirements for Inductive Voltage Transformers. IEC: Geneva, Switzerland.
• Kuffel, J., & Kuffel, P. (2000). High voltage engineering fundamentals. Elsevier.
• Mingotti, A., Peretto, L., Nalli, A., Pau, M., & Ponci, F. (2020, May). Analysis of Ratio and Phase Errors over Time for Low-power Voltage Transformers. In 2020 IEEE International Instrumentation and Measurement Technology Conference (I2MTC) (pp. 1-6). 25-28 June 2020, Hırvatistan.
• Mingotti, A., Peretto, L., & Tinarelli, R. (2018, May). Low-power Voltage Transformer Accuracy Class Effects on the Residual Voltage Measurement. In 2018 IEEE International Instrumentation and Measurement Technology Conference (I2MTC) (pp. 1-6). 14-17 May 2018, ABD.
• Mingotti, A., Bartolomei, L., Peretto, L., & Tinarelli, R. (2020). On the Long-Period Accuracy Behavior of Inductive and Low-Power Instrument Transformers. Sensors, 20(20), 5810.
• Park, J. H., (1962). Special Shielded Resistor for high-voltage DC measurements. J. Res. Nat. Bur. Stand., 66(19–24).
• Ryan, H. M., (2001). High-Voltage Engineering and Testing, Institution of Electrical Engineers’ Publication,726, Wiltshire.