Your search keyword '"Sima, Wenxia"' showing total 10 results

1. A Novel Active Mechanical HVDC Breaker With Consecutive Interruption Capability for Fault Clearances in MMC-HVDC Systems.

Author

Sima, Wenxia, Fu, Zhengzheng, Yang, Ming, Yuan, Tao, Sun, Potao, Han, Xue, and Si, Yan

Subjects

*ELECTRIC potential, *ELECTRIC circuits, *CAPACITORS, *ELECTRIC inductors, *SIMULATION methods & models

Abstract

The lack of dc fault clearance capability is a major obstacle that restricts the development of high-voltage direct current (HVdc) systems. Employing an active mechanical dc circuit breaker (M-DCCB) is an effective method to handle the dc fault. However, the existing active M-DCCBs can interrupt the fault current once but have problems in making the second interruption instantly in case of reclosing a permanent dc fault. In this paper, a novel topology of the active M-DCCB is proposed by inserting a precharged capacitor into a bridge formed by four spark gap switches. The operating strategy for the proposed M-DCCB is discussed to handle the dc faults. Its parameters, including the oscillation inductor and the oscillation capacitor, are determined by inequations derived from the requirements of dc fault interruption. The selection standard for the spark gap switch is set based on its breakdown characteristics. Finally, simulations are conducted to investigate the performance of the proposed M-DCCB. Results show that the capacitor can accumulate a sufficiently large reverse charge voltage automatically charged by the fault current. The proposed active M-DCCB topology and the dc fault handling strategy can interrupt the dc fault in HVdc power systems consecutively. [ABSTRACT FROM AUTHOR]

Published

2019

2. Suppressing ferroresonance in potential transformers using a model-free active-resistance controller.

Author

Yang, Ming, Sima, Wenxia, Sun, Potao, Yuan, Tao, Chen, Lijun, and Duan, Pan

Subjects

*THYRISTORS, *ELECTRIC transformers, *RESONANCE, *ELECTRIC potential, *SIMULATION methods & models

Abstract

Ferroresonance, excited by saturated electromagnetic voltage transformers, can severely damage power systems because it produces long duration large overvoltages. In this paper, a method is developed to eliminate potential transformer (PT) ferroresonance through a model-free method. First, a structural diagram of the ferroresonance eliminating device is established based on a practical ferroresonant circuit. The effect of the adjustable parameters of the device is investigated, including resistance, pulse frequency, and pulse duty cycle. Then, Iterative control strategies are developed to adjust the gate signal duty cycle of the controller for limiting the ferroresonance to a normal status and then switching off the elimination device. Finally, simulations are conducted demonstrating that the method proposed was effective. [ABSTRACT FROM AUTHOR]

Published

2018

3. Grounding Resistance Measurement Method Based on the Fall of Potential Curve Test Near Current Electrode.

Author

Yuan, Tao, Bai, Yang, Sima, Wenxia, Xian, Chengchen, Peng, Qingjun, and Guo, Runsheng

Subjects

ELECTRIC current grounding, ELECTRIC resistance, ELECTRODES, ELECTRIC potential, ELECTRIC current measurement

Abstract

Grounding resistance is an important basic index used to ensure the safety and reliability of grounding systems. In this paper, a method for grounding resistance measurement based on the fall of potential curve is proposed that can be performed using a 2–2.5D lead wire length. In this method, the potential distribution near the auxiliary current electrode is tested and is used as the main analysis and measurement parameter. Based on the relationship between the potential distribution generated by the grounding grid and the current electrode, the grounding resistance of the grounding grid can be deduced. First, the voltages between the grounding grid and the earth surface potential near the current electrode are measured; then, the ground potential rise (GPR) of the grounding grid is calculated through theoretical analysis and numerical calculation; and finally, the grounding resistance is calculated by dividing the potential by the test current. This method avoids the complex task of accurate compensation point location required for traditional measurement methods, and can be performed easily and quickly using a short lead wire. Measurement results from spot testing show that the proposed method can meet the accuracy requirements of engineering testing. [ABSTRACT FROM AUTHOR]

Published

2017

4. Study on voltage-number characteristics of transformer insulation under transformer invading non-standard lightning impulses.

Author

Sun, Potao, Sima, Wenxia, Yang, Ming, Lan, Xing, and Wu, Jingyu

Subjects

*TRANSFORMER insulation, *ELECTRIC potential, *LIGHTNING, *ELECTRIC lines, *POWER transformers

Abstract

According to the IEC Standard, the insulation performances of power apparatus under lightning impulse voltages are evaluated by the withstand test of standard lightning impulse voltage, with the wave front/tail time of 1.2/50 ?s. However, the standard lightning impulse voltage originally obtained from the transmission lines or triggering lightning towers, is quite different from the invading lightning impulse voltage in the power transformers. Hence, in this work, an attempt has been made to obtain the waveform characteristics of invading lightning impulses in power transformers using an overvoltage online monitoring system. Energy Method was then proposed to convert the recorded oscillatory waveform into double-exponential waveform defined by IEC Standard. And the statistical waveform parameters of recorded invading lightning impulses, namely, the non-standard lightning impulses, were determined based on the Energy Method. Current insulation assessment methods, for example, the V-t characteristics, are far from satisfactory to meet the demand of insulation design for the power apparatus, whereas the impulse breakdown voltage-number of voltage applications characteristics (V-N characteristics) could well evaluate the long term performance of insulation system. Therefore, we experimentally identified the V-N characteristics of oil paper insulation under impulse voltage with different waveforms, including non-standard lightning impulse voltage, and then mathematically analyzed the obtained data. At last, the influence of wave front/tail time on the V-N characteristics of oil paper insulation was experimentally studied. The test results indicate that the insulation performances of oil paper insulation under repeated nonstandard lightning impulse voltages and under standard switching impulse voltages were better than that under repeated standard lightning impulse voltages. And the capacity to withstand repeated voltage became increasingly stronger with the increase in wave front time or the decrease in wave tail time. The breakdown voltage, however, was only related to the wave front time of applied impulse voltage. [ABSTRACT FROM AUTHOR]

Published

2015

5. Effect of space charge on the accumulative characteristics of oil paper insulation under repeated lightning impulses.

Author

Sima, Wenxia, Sun, Potao, Yang, Ming, Yang, Qing, and Wu, Jingyu

Subjects

*ELECTRIC insulators & insulation, *ELECTRIC equipment, *LIGHTNING, *SPACE charge, *ELECTRIC potential, *POWER transformers

Abstract

Repeated impulses have long been considered to affect the insulation properties of electrical equipment. This interesting but rarely studied phenomenon may pose great risks to the reliable operation of power equipment. Therefore, in this work, we focus on the accumulative effect of repeated lightning impulses on the oil-impregnated paper (OIP) used in power transformers. Specifically, we study the effect of space charge on the accumulative characteristics of OIP. A repetitive impulse accumulating test platform was set up, and the tests were conducted to obtain the accumulative characteristics of OIP under repeated lightning impulses. The accumulative characteristics of OIP with various interval time were experimentally identified to study the influence of interval time on the accumulative effect. Then, space charge in OIP samples were investigated using the pulsed electro-acoustic technique. Charge behavior in OIP was analyzed under different conditions, i.e., changing the applied times, amplitude and interval time of the applied lightning impulses. Charge injection and transport occurred during lightning impulse accumulation. The increased application of lightning impulses, high applied voltage, and short interval time contributed to the accumulation and transport of space charges. At last, the possible mechanisms of the accumulative effect are discussed in this article based on the experimental results. [ABSTRACT FROM AUTHOR]

Published

2015

6. Effects of conductivity and permittivity of nanoparticle on transformer oil insulation performance: experiment and theory.

Author

Sima, Wenxia, Shi, Jian, Yang, Qing, Huang, Sisi, and Cao, Xuefei

Subjects

*NANOPARTICLES, *PERMITTIVITY, *TITANIUM dioxide, *INSULATING oils, *INSULATING materials, *PHYSICS experiments, *POTENTIAL well

Abstract

The mechanisms by which conductive and dielectric nanoparticles (NPs) trap electrons are explained by the potential well distribution caused by induced or polarized charges on NPs. Thus, the distributions of surface and saturation charges on conductive and dielectric NPs are determined. Given conductive Fe3O4, semiconductive TiO2, and dielectric Al2O3 NPs, insulation performance tests are conducted and ionization models of nanofluids (NFs) based on transformer oil are developed. These models are compared with those of NFs based on pure oil. The NP whose conductivity or permittivity does not match that of the dielectric liquid has a potential well and an increased amount of saturation charges on its interface. This NP influences streamer development strongly and enhances the breakdown of oilbased NF. [ABSTRACT FROM AUTHOR]

Published

2015

7. Shed Configuration Optimization for Ice-Covered Extra High Voltage Composite Insulators.

Author

Qing Yang, Sima, Wenxia, Jiazhuo Deng, Caixin Sun, and Jianlin Hu

Subjects

*CONFIGURATIONS (Geometry), *ICE sheets, *ELECTRIC potential, *PERFORMANCE evaluation, *ELECTRIC lines, *ELECTRIC fields

Abstract

The electrical performance of composite insulators with adhered ice is less than that of porcelain or glass insulator strings, which is mainly caused by the shed configuration differences. In this paper, the shed con-figuration optimization for ice-covered Extra High Voltage (EHV) composite insulators is discussed in order to improve the electrical performance of ice-covered composite insulators. The effects of the position and length of the air gaps on the electric field distribution of ice-covered composite insulators are investigated and analyzed based on the electric field calculation model. The basic optimization principles of the shed con-figuration for ice-covered composite insulators are based on the electric field calculation results. Moreover, the artificial icing flashover tests on the ice-covered composite insulators with different shed configurations were carried out in artificial climate chamber, and the flashover path was recorded by a high speed cam-era. According to the flashover voltage and the flashover path of composite insulators with different shed configurations, it can be concluded that the composite insulators with large shed spacing and various shed diameters have better electrical performance and can be used in the transmission lines across the icing area [ABSTRACT FROM AUTHOR]

Published

2012

8. Optimization and Experimental Study of the Semi-Closed Short-Gap Arc-Extinguishing Chamber Based on a Magnetohydrodynamics Model.

Author

Jia, Wenbin, Sima, Wenxia, Yuan, Tao, Yang, Ming, and Sun, Potao

Subjects

*ELECTRIC potential, *FINITE element method, *HEAT transfer, *MICROSTRUCTURE, *VACUUM arcs

Abstract

The multi-chamber arc-extinguishing structure (MAS), which consists of a lot of semi-closed short-gap arc-extinguishing chambers (SSAC) in series, can be used in parallel gap lightning protection devices to improve the ability to extinguish power frequency follow current. The arc-extinguishing ability of single SSAC directly affects the arc-extinguishing performance of the whole MAS. Therefore, the arc-extinguishing performance of MAS can be improved by optimizing single SSACs. A two-dimensional model of the arc plasma in a SSAC is built based on the magneto-hydrodynamic (MHD) theory. The motion characteristics of an arc in the SSAC are simulated and analyzed. An optimization method of the SSAC structure is proposed. Finally, an impact test platform is built to verify the effectiveness of the optimized SSAC structure. Results show that the short-gap arc forms a high-speed airflow in the SSAC and the arc plasma sprays rapidly to the outlet until the arc is extinguished at its current zero-crossing point. The amplitude of airflow velocity in the optimized structure can be increased to about 8-fold the velocity in the basic structure. Experiments also show that the dissipation time of an arc in the optimized SSAC is 79.2 μs, which is much less than that in the original structure (422.4 μs). [ABSTRACT FROM AUTHOR]

Published

2018

9. An application area of C60: Overall improvement of insulating oil's electrical performance.

Author

Sun, Potao, Sima, Wenxia, Chen, Jiaqi, Zhang, Dingfei, Jiang, Xiongwei, and Chen, Qiulin

Subjects

*COMPOSITE materials, *NANOPARTICLES, *ELECTRIC conductivity, *X-ray diffraction, *ELECTRIC potential

Abstract

We prepared nano-C60 based insulating oil, which has the potential to overcome the application barriers of nanomodified insulating oil. We find that nano-C60 based insulating oil has an excellent stability. Its electrical performance increases by 17.9%, 9.3%, and 8.3% for AC and positive/negative lightning impulse voltage, respectively. We believe that C60 molecules have a strong capacity to absorb electrons and can capture photons in a streamer, which may weaken photoionization in the streamer and thereby improve the electrical performance of insulating oil. [ABSTRACT FROM AUTHOR]

Published

2018

10. Measurement and analysis of transient overvoltage distribution in transformer windings based on reduced-scale model.

Author

Yang, Qing, Chen, Yong, Sima, Wenxia, and Zhao, Hongbin

Subjects

*ELECTRIC potential, *ELECTRIC power distribution, *ELECTRIC generators, *ELECTRIC windings, *POWER transformers, *OVERVOLTAGE

Abstract

Non-uniform voltage distribution under transient voltage is a primary cause of breakdown of the major insulation of power transformers. Actual power transformer winding has no tap, and is unable to directly measure impulse voltage distribution. Research on the measurement of impulse voltage distribution is important and practical in engineering. According to the relationship between physical quantities, the present study established a simplified shrinkage ratio criterion. Then, the researchers designed a similar ratio 1/20, typed 10 kVA 220 V/2400 V, tapped transformer reduced-scale model, and used the finite element simulation software to simulate the reduced-scale and the original model of the electromagnetic field. Finally, a test platform was built to measure nanosecond pulse voltage and lightning impulse voltage distribution in transformer winding. The researchers also studied the nanosecond pulse width and lightning wave tail time affecting the winding voltage distribution. [ABSTRACT FROM AUTHOR]

Published

2016