Measurement Method for Resistive Current Components of Metal Oxide Surge Arrester in Service

Zhong-jun, FU; Wang, Jianyu; Bretãs, Arturo S.; Ou, Yun; Zhou, Genyuan

doi:10.1109/tpwrd.2017.2776955

Cited by 20 publications

(12 citation statements)

References 25 publications

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“…For verification of the described measuring principle that is based on (15) to (18), the experimental test-bench system was built, as shown in Figure 11. The Surge Arrester Monitoring Device prepared the current measurement results into the form that is required for further processing.…”

Section: Resultsmentioning

confidence: 99%

“…The leakage current was calibrated appropriately, and the procedure described in Section 2.3 was applied from the files that were obtained from the SAMD. The resistive component of leakage current was calculated using (15) to (18). Table 6 summarises the measurement results.…”

Section: Measurement Resultsmentioning

confidence: 99%

“…The algorithm was verified while considering (15) to (18) after measuring of the unknown arrester, but it was extracted from a set of the same type. The arrester leakage current was sampled in the range ϕ ∈ (60, 180)[ • ] and the value of I t_avg was obtained.…”

Section: Verification Of the Proposed Algorithmmentioning

confidence: 99%

“…Here, the total leakage current is decomposed to study the impact of different parameters on the decomposition accuracy. Additionally, many methods have been introduced for measuring the resistive component of the total leakage current [ 18 , 19 ]. However, researchers in the area have also paid significant attention to evaluating the surge arrester’s condition to reduce network losses.…”

Section: Introductionmentioning

confidence: 99%

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Extracting the Resistive Current Component from a Surge Arrester’s Leakage Current without Voltage Reference

Vončina¹,

Pihler

Milanovič

2021

Sensors

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This article presents the development of the theoretical background and the design of an electronic device for monitoring the condition of a gapless Metal Oxide Surge Arrester (MOSA). The device is intended to be used online. Because of the inaccessibility and possible remote location of most surge arresters, it is equipped with a communication system, allowing for the device to convey the measurement of the surge arrester characteristics under any conditions. It is possible to determine the condition of the MOSA by gathering measurements of the surge arrester’s resistive component of leakage current. The leakage current information is sent via data transfer unit to a server and, after interpretation, will be forwarded to the authorised personnel through the surge arrester control centre.

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Section: Resultsmentioning

confidence: 99%

Section: Measurement Resultsmentioning

confidence: 99%

Section: Verification Of the Proposed Algorithmmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Extracting the Resistive Current Component from a Surge Arrester’s Leakage Current without Voltage Reference

Vončina¹,

Pihler

Milanovič

2021

Sensors

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“…Nowadays [20,21], gapless lightweight metal-oxide type line surge arresters (LSA) represent a very promising solution since they can improve the protection level, offering special features inherent gapless structure, e.g., quick response to surges, high energy dissipation capability, and freedom from pollution, that may introduce spurious resistive components [22].…”

Section: Introductionmentioning

confidence: 99%

Analysis of Metal Oxide Varistor Arresters for Protection of Multiconductor Transmission Lines Using Unconditionally-Stable Crank–Nicolson FDTD

et al. 2020

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Surge arresters may represent an efficient choice for limiting lightning surge effects, significantly reducing the outage rate of power lines. The present work firstly presents an efficient numerical approach suitable for insulation coordination studies based on an implicit Crank–Nicolson finite difference time domain method; then, the IEEE recommended surge arrester model is reviewed and implemented by means of a local implicit scheme, based on a set of non-linear equations, that are recast in a suitable form for efficient solution. The model is proven to ensure robustness and second-order accuracy. The implementation of the arrester model in the implicit Crank–Nicolson scheme represents the added value brought by the present study. Indeed, its preserved stability for larger time steps allows reducing running time by more than 60 % compared to the well-known finite difference time domain method based on the explicit leap-frog scheme. The reduced computation time allows faster repeated solutions, which need to be looked for on assessing the lightning performance (randomly changing, parameters such as peak current, rise time, tail time, location of the vertical leader channel, phase conductor voltages, footing resistance, insulator strength, etc. would need to be changed thousands of times).

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Study on Analysis Method of Zinc Oxide Line Arrester Fracture

Yang,

Tian,

Chen

et al. 2023

Lecture Notes in Electrical Engineering

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Measurement Method for Resistive Current Components of Metal Oxide Surge Arrester in Service

Cited by 20 publications

References 25 publications

Extracting the Resistive Current Component from a Surge Arrester’s Leakage Current without Voltage Reference

Extracting the Resistive Current Component from a Surge Arrester’s Leakage Current without Voltage Reference

Analysis of Metal Oxide Varistor Arresters for Protection of Multiconductor Transmission Lines Using Unconditionally-Stable Crank–Nicolson FDTD

Study on Analysis Method of Zinc Oxide Line Arrester Fracture

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