Dual LiNbO3 Crystal-Based Batteryless and Contactless Optical Transient Overvoltage Sensor for Overhead Transmission Line and Substation Applications

Advanced high-voltage and overvoltage measurement techniques are required for smart grid construction. The existing overvoltage measurement methods that are currently used for power system measurements are mostly based on the use of electromagnetic voltage transformers and capacitive voltage transformers, which have contradiction in measuring accuracy, measuring distance, antijamming, and system compatibility. A batteryless sensor for contactless measurement of the overvoltage on overhead transmission lines based on a combination of the electrooptic effect in LiNbO3 with stray capacitance in the air is designed in this work. On the basis of this design, a dual-crystal structure-based electrooptic conversion unit is presented that eliminates the natural birefringence and improves the operating stability of the sensor. Testing platforms were set up to measure the characteristics of the sensor in thermal stability. In combination with a data acquisition device, the newly designed sensor was applied to online monitoring of the overvoltage in the ac bus and the overhead transmission lines of a 500-kV transformer station and a ±500-kV convertor station in the China Southern Power Grid.

[1]  Douglas J. Thomson,et al.  Passive Wireless Sensor for Measuring AC Electric Field in the Vicinity of High-Voltage Apparatus , 2016, IEEE Transactions on Industrial Electronics.

[2]  K. Hidaka,et al.  Directly High-Voltage Measuring System Based on Pockels Effect , 2013, IEEE Transactions on Power Delivery.

[3]  Jinliang He,et al.  Lightning Impulse Corona Characteristic of 1000-kV UHV Transmission Lines and Its Influences on Lightning Overvoltage Analysis Results , 2013, IEEE Transactions on Power Delivery.

[4]  A. Haddad,et al.  Wireless measurement system for a large-scale grounding electrode test facility , 2013, 2013 48th International Universities' Power Engineering Conference (UPEC).

[5]  Thomas Johnson,et al.  Calibrated Single-Contact Voltage Sensor for High-Voltage Monitoring Applications , 2015, IEEE Transactions on Instrumentation and Measurement.

[6]  Toshihiko Yoshino,et al.  Measurement of AC electric power based on dual transverse Pockels effect , 2001, IEEE Trans. Instrum. Meas..

[7]  Xi Fang,et al.  3. Full Four-channel 6.3-gb/s 60-ghz Cmos Transceiver with Low-power Analog and Digital Baseband Circuitry 7. Smart Grid — the New and Improved Power Grid: a Survey , 2022 .

[8]  Peter Crossley,et al.  Test and analysis of harmonic responses of high voltage instrument voltage transformers , 2014 .

[9]  Hui Li,et al.  An Analysis on the Optimization of Closed-Loop Detection Method for Optical Voltage Sensor Based on Pockels Effect , 2014, Journal of Lightwave Technology.

[10]  P. P. Chavez,et al.  230 kV Optical Voltage Transducers Using Multiple Electric Field Sensors , 2002, IEEE Power Engineering Review.

[11]  Qing Yang,et al.  Non-contact measurement of lightning and switching transient overvoltage based on capacitive coupling and pockels effects , 2016 .

[12]  A. Lipsky,et al.  Errors in measuring of high voltage harmonics in the medium voltage power networks , 2014, 2014 IEEE International Energy Conference (ENERGYCON).

[13]  Yang Wang,et al.  Online Overvoltage Prevention Control of Photovoltaic Generators in Microgrids , 2012, IEEE Transactions on Smart Grid.

[14]  Taskin Koçak,et al.  Smart Grid Technologies: Communication Technologies and Standards , 2011, IEEE Transactions on Industrial Informatics.

[15]  Juan A. Martinez,et al.  Switching Overvoltage Measurements and Simulations—Part I: Field Test Overvoltage Measurements , 2014, IEEE Transactions on Power Delivery.

[16]  Zhiqian Bo,et al.  Effective Overvoltage Source Identification Scheme for Machines Working in Parallel , 2012, IEEE Transactions on Energy Conversion.

[17]  Josemir Coelho Santos,et al.  Pockels high-voltage measurement system , 1999 .

[18]  K. Bohnert,et al.  Fiber optic voltage sensor for 420 kV electric power systems , 2000 .

[19]  J. Warner,et al.  The temperature dependence of the refractive indices of pure lithium niobate , 1966 .

[20]  Jianchao Zheng,et al.  A new multi-gap spark switch connected with frequency-dependent network for EHV overvoltage protection applications , 2012, IEEE Transactions on Dielectrics and Electrical Insulation.

[21]  Chiranjib Koley,et al.  Intensity-Modulated Fiber Bragg Grating Sensor for Detection of Partial Discharges Inside High-Voltage Apparatus , 2016, IEEE Sensors Journal.

[22]  Eleonora Riva Sanseverino,et al.  Remote voltage synchronization for wireless Partial Discharge diagnostics , 2016, 2016 IEEE International Conference on Dielectrics (ICD).

[23]  Min Lei,et al.  Research on the Error Characteristics of a 110 kV Optical Voltage Transformer under Three Conditions: In the Laboratory, Off-Line in the Field and During On-Line Operation , 2016, Sensors.

[24]  Fabrizio Marignetti,et al.  Fiber Bragg Grating Sensor for Electric Field Measurement in the End Windings of High-Voltage Electric Machines , 2016, IEEE Transactions on Industrial Electronics.

[25]  Juri Jatskevich,et al.  High-Frequency Modeling of the Long-Cable-Fed Induction Motor Drive System Using TLM Approach for Predicting Overvoltage Transients , 2010, IEEE Transactions on Power Electronics.

[26]  Nicolas A. F. Jaeger,et al.  Accurate Voltage Measurement by the Quadrature Method , 2002, IEEE Power Engineering Review.