Development of Equipment and Application of Machine Learning Techniques Using Frequency Response Data for Cap Damage Detection of Porcelain Insulators

Choi, In Hyuk; Koo, Ja Bin; Son, Ju Am; Yi, Jun; Yoon, Young-Geun; Oh, Tae Keun

doi:10.3390/app10082820

Cited by 7 publications

(3 citation statements)

References 27 publications

(40 reference statements)

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“…The most common places of partial discharges are paper insulation, electrical insulating liquid, culvert surface, and metal elements of the transformer that are under voltage. Such places may be characterized by insufficient electrical strength, which is the result of the insulation aging processes, or too-high values of electric field strength, which is the result of the occurrence of sharp edges of metal parts [24][25][26][27][28]. Losses caused by partial discharges are very small and their value usually does not exceed 1 W. The value of these losses depends on many factors, such as transformer voltage, temperature, degree of contamination of the surface of bushing insulators, degree of aging of insulation materials, and level of moisture in both paper insulation and insulating liquid.…”

Section: No-load Lossesmentioning

confidence: 99%

Determination of Dielectric Losses in a Power Transformer

Nadolny

2022

Energies

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The article presents a method of determining dielectric losses that occur in insulating materials in a power transformer. These losses depend mainly on the electric field stress, pulsation, dielectric loss coefficient, and electrical permittivity of insulating materials. These losses were determined by integrating an expression describing unit losses. The determined dielectric losses were compared with the total losses of the transformer. It turned out that dielectric losses are a fraction of a percent of the total losses. The influence of the electrical permittivity of the insulating liquid and paper insulation on the value of dielectric losses was investigated. This influence was ambiguous, which is characteristic of stratified systems made of materials with different permittivity. An analysis of the influence of the dielectric loss coefficient tan(delta) on the value of dielectric losses in the transformer was carried out. The impact of this coefficient on the amount of dielectric losses turned out to be directly proportional.

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Section: No-load Lossesmentioning

confidence: 99%

Determination of Dielectric Losses in a Power Transformer

Nadolny

2022

Energies

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“…Li et al [25] used two back propagation neural networks for partial discharge recognition in gas insulated switchgear. Choi et al [26] tested various ML methods like bagging, k-nearest neighbor, support vector machines and linear discriminant analysis to detect cap damage of porcelain insulators using frequency response functions. An increasing number of researches that use deep learning (DL) neural networks for PD classification can be noticed recently.…”

Section: Introductionmentioning

confidence: 99%

Detection and Localization of Partial Discharge in Connectors of Air Power Lines by Means of Ultrasonic Measurements and Artificial Intelligence Models

Samaitis

Mažeika

Jankauskas

et al. 2020

Sensors

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According to the statistics, 40% of unplanned disruptions in electricity distribution grids are caused by failure of equipment in high voltage (HV) transformer substations. These damages in most cases are caused by partial discharge (PD) phenomenon which progressively leads to false operation of equipment. The detection and localization of PD at early stage can significantly reduce repair and maintenance expenses of HV assets. In this paper, a non-invasive PD detection and localization solution has been proposed, which uses three ultrasonic sensors arranged in an L shape to detect, identify and localize PD source. The solution uses a fusion of ultrasonic signal processing, machine learning (ML) and deep learning (DL) methods to classify and process PD signals. The research revealed that the support vector machines classifier performed best among two other classifiers in terms of sensitivity and specificity while classifying discharge and surrounding noise signals. The proposed ultrasonic signal processing methods based on binaural principles allowed us to achieve an experimental lateral source positioning error of 0.1 m by using 0.2 m spacing between L shaped sensors. Finally, an approach based on DL was suggested, which allowed us to detect a single PD source in optical images and, in such a way, to provide visual representation of PD location.

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“…The results of numerical example validation indicate that this method has good damage identification performance. Keywords: Building Structure; Continuous Beam; Damage; Deflection; Curvature 1 引言两跨连续梁结构在实际工程中有着广泛的应用，例如连续梁桥、架空管道等。对于服役较久的两跨连续梁结构，需及时发现损伤信息以确保其安全运行。两跨连续梁上可能出现的损伤情形有多种，但在理论上一般可以局部刚度的变化来代表损伤 [1][2][3]。在进行损伤识别时，首先选定某一结构性能指标，然后根据其在损伤前后的变化来识别损伤信息(刚度变化)。目前常用的结构性能指标包括静力性能指标与动力性能指标两大类：静力性能指标包括位移 [4][5][6]、挠度曲率 [7]、应变 [8]等，动力性能指标包括频率 [9]、振型 [10]、曲率模态 [11]、应变模态 [12]等。其中，挠度曲率是值得重点关注的指标之一，尤其是根据静力挠度数据和中心差分法得到的挠度差分曲率，可以反映出结构上由损伤出现造成的局部刚度变化，从而实现损伤识别。同时，挠度差分曲率指标值的获取过程简单，利用光纤光栅等先进传感器能达到很高的数据精度。对于梁结构，基于挠度差分曲率的损伤识别方法首先应用于简支梁这类静定梁 [7,[13][14][15]…”

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Damage Detection Method of Simply Supported Beams Based on Difference of Nearby Difference Curvature Index

Yi-lin,

Yu,

Jia-qi

2023

cear

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In order to improve the effectiveness and convenience of damage identification of two-span continuous beams, a new damage identification index D i based on the deflection data of beam under concentrated load, which takes local flexural stiffness and shear stiffness as damage identification parameter, was proposed. The damage detection method based on D i includes four main steps: arranging vertical deflection measurement points at equal intervals on the beam body and applying a concentrated load F at the mid span position of one of the spans. After measuring the y i value at each measurement point, the differential deflection curvature value 1/ρ i can be calculated; After obtaining specific values of D i according to the definition, a graph with D i as the vertical coordinate and the positions of each measuring point on the longitudinal axis of the beam as the horizontal coordinate can be drawn; The mutation position on the graph can

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Development of Equipment and Application of Machine Learning Techniques Using Frequency Response Data for Cap Damage Detection of Porcelain Insulators

Cited by 7 publications

References 27 publications

Determination of Dielectric Losses in a Power Transformer

Determination of Dielectric Losses in a Power Transformer

Detection and Localization of Partial Discharge in Connectors of Air Power Lines by Means of Ultrasonic Measurements and Artificial Intelligence Models

Damage Detection Method of Simply Supported Beams Based on Difference of Nearby Difference Curvature Index

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