مقاله انگلیسی رایگان در مورد تشخیص تخلیه جزئی خودکار با استفاده از تبدیل موجک کراس – الزویر 2020

 

مشخصات مقاله
ترجمه عنوان مقاله تشخیص تخلیه جزئی خودکار با استفاده از تبدیل موجک کراس در سیستم های اندازه گیری مشترک کابل ولتاژ بالا با استفاده از دو سنسور با قطبیت مخالف
عنوان انگلیسی مقاله Automatic partial discharge recognition using the cross wavelet transform in high voltage cable joint measuring systems using two opposite polarity sensors
انتشار مقاله سال 2020
تعداد صفحات مقاله انگلیسی 8 صفحه
هزینه دانلود مقاله انگلیسی رایگان میباشد.
پایگاه داده نشریه الزویر
نوع نگارش مقاله
مقاله پژوهشی (Research Article)
مقاله بیس این مقاله بیس نمیباشد
نمایه (index) Scopus – Master Journals List – JCR
نوع مقاله ISI
فرمت مقاله انگلیسی  PDF
ایمپکت فاکتور(IF)
5.627 در سال 2019
شاخص H_index 100 در سال 2020
شاخص SJR 1.260 در سال 2019
شناسه ISSN 0142-0615
شاخص Quartile (چارک) Q1 در سال 2019
مدل مفهومی ندارد
پرسشنامه ندارد
متغیر ندارد
رفرنس دارد
رشته های مرتبط برق
گرایش های مرتبط الکترونیک، مدارهای مجتمع الکترونیک، انتقال و توزیع، سیستم های الکترونیک دیجیتال
نوع ارائه مقاله
ژورنال
مجله  مجله بین المللی سیستم های انرژی و برق – International Journal Of Electrical Power & Energy Systems
دانشگاه Delft University of Technology, Electrical Sustainable Energy Department, Delft, the Netherlands
کلمات کلیدی تخلیه های جزئی (PD)، تبدیل موجک، تبدیل موجک کراس، جداسازی نویز، ترانسفورماتور جریان با فرکانس بالا (HFCT)، اتصال کابل ولتاژ بالا
کلمات کلیدی انگلیسی partial discharges (PD)، Wavelet transform، Cross wavelet transform، Noise separation، high-frequency current transformer (HFCT)، High voltage cable joint
شناسه دیجیتال – doi
https://doi.org/10.1016/j.ijepes.2019.105695
کد محصول E14940
وضعیت ترجمه مقاله  ترجمه آماده این مقاله موجود نمیباشد. میتوانید از طریق دکمه پایین سفارش دهید.
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فهرست مطالب مقاله:
Abstract

1- Introduction

2- Experimental setup

3- Cross wavelet transform

4- Wavelet and scales selection

5- Methodology

6- Results

7- Conclusions

References

بخشی از متن مقاله:

Abstract

This paper presents a new wavelet analysis approach in partial discharges cable joint measurements in noisy environments. The proposed technique uses the Cross Wavelet Transform (XWT) to separate PD signals from noise and external disturbances in partial discharges measurements in cable joints using two opposite polarity sensors. The partial discharge measurements were performed during impulse and superimposed voltages, leading to a huge amount of noise and pulse shaped external disturbances. The XWT foundations, the experimental setup and the XWT methodology proposed are presented together with the results of the recognition of PD originated in the cable joint. In the experiments, 51,898 signals were acquired, in which 733 were PD signals from the joint and 51,165 corresponded to noise or external disturbances. The XWT performance was studied, finding that 97% of the PD signals were correctly separated by the technique proposed. The results demonstrate the effectivity of the XWT in separating PD signals from noise and external disturbances in this particular measuring system configuration.

Introduction

Nowadays, Partial Discharges (PD) detection is an essential tool for the diagnosis of high-voltage equipment because of their accuracy to detect and quantify defects and damages in the dielectric insulation, where the detection implies the measurement, acquisition, storage and processing of the PD phenomenon [1]. In general, the most widespread PD detection system is based on electrical measurements, in which the PD signals are acquired in the form of individual or series of electrical pulses. In offline PD cable field tests and in laboratory tests, capacitive coupled sensors installed at the cable ends are used [2,3]. In cable systems, statistically most of the partial discharges come from either the cable terminations or the cable joints, being necessary to locate them by time domain reflectometry techniques. In spite of the PD measurement has been exhaustively researched over the years, the separation of PD pulses from noise is one of the main challenges, especially in online applications. Therefore, noise contamination is one of the significant problems of PD detection [4], because noise, disturbances and interferences can give rise to complex Phase Resolved Partial Discharges (PRPD) patterns or clusters, leading to misleading interpretations [5]. For this reason, several studies [1,4,6–13] have focused on the PD pulses separation and denoising techniques for PD measurements. Among these studies, the wavelet transform has been broadly used because is capable of locating time and frequency components allowing the analysis of aperiodic signals with irregular and transition features, such as the partial discharges [1]. In the wavelet analysis techniques, the Discrete Wavelet Transform (DWT) has been used extensively for denoising PD signals. In general, in the DWT denoising, the wavelet coefficients are calculated for a given signal and then the coefficients are passed through a threshold (soft or hard) and followed by the reconstruction of the signal by taking the inverse wavelet transform of the modified DWT coefficients. However, a major problem that most of these denoising techniques face is the ingress of external interferences having time-frequency characteristics similar to the partial discharge signals (pulse shaped disturbances); for instance, periodic pulse shaped interferences from power electronics or another periodic switching [7], PD and corona discharges from the external power system, electrical pulses from switching operations, lightings, etc. This external noise can cause a false indication of PD activity, jeopardising the PD measurements as a diagnostic tool. To reduce the false indications, in PD measurement systems more than one electrical sensor (HFCTs, UHF antennas, coupling capacitors, etc.) is used, meaning that multiple waveforms are simultaneously acquired, because recording each signal through different sensors may provide extra useful information about the real nature of the waveform recorded. Tools like the correlation and trend analysis can provide the significance of relationships between the signals recorded [14].

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