Your search keyword '"OUCHEN, Lyamine"' showing total 5 results

1. Performance Evaluation of cap and pin insulator under pollution conditions using Finite element method (FEM).

Author

ZORIG, Assam, BELHOUCHET, Khaled, and OUCHEN, Lyamine

Subjects

FINITE element method, CAPS (Headgear), ELECTRIC fields, POLLUTION, HIGH voltages

Abstract

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Published

2024

2. EXPERIMENTAL INVESTIGATION ON DIELECTRIC PROPERTIES OF 1512L INSULATOR USING FINITE ELEMENT ANALYSIS (FEM).

Author

BELHOUCHET, Khaled, ZEMMIT, Abderrahim, OUCHEN, Lyamine, ALTI, Nadjim, and ZORIG, Assam

Subjects

FINITE element method, DIELECTRIC properties, NUMERICAL analysis

Abstract

In this work, a study on a cap and pin insulator (1512L) is proposed to evaluate the distribution of the electric field and the potential along the insulator under different conditions. A computational and experimental study for the examination of a real insulators model is assessed. Tests on contaminated insulators in the laboratory under the suggested conditions have been carried out. Finite element methods (FEM) have been employed in the numerical analysis to assess the electrical properties of the insulator under the suggested contamination profiles, including potential and electric field. The study proposed in this paper provides an effective and practical tool for analysis and enhance the dielectric properties of the studied insulator. [ABSTRACT FROM AUTHOR]

Published

2024

3. EFFECTS ANALYSIS OF THE POLLUTION LAYER PARAMETERS ON A HIGH-VOLTAGE PORCELAIN CYLINDRICAL INSULATOR USING RESPONSE SURFACE METHODOLOGY.

Author

BELHOUCHET, Khaled, BAYADI, Abdelhafid, ALTI, Nadjim, and OUCHEN, Lyamine

Subjects

RESPONSE surfaces (Statistics), FLASHOVER, ELECTRIC breakdown, POLLUTION, ELECTRIC fields, PORCELAIN, ELECTRIC insulators & insulation

Abstract

The influences of the pollution layer parameters including; conductivity, position and length on the performance of high-voltage cylindrical insulator were investigated. Parameters effects and their interactions have been assessed and determined using the variance statistical technique and the relation between parameters and the flashover voltage, maximum electric field and the breakdown strength is modeled by the response surface methodology (RMS). The 3D model from Comsol Multiphysics was used for modeling and the FEM method was utilized for simulations. The findings demonstrate that the flashover voltage of the non-uniformly contaminated surface is primarily affected by the pollution layer length. Simulation results show that the intensity of the electric field rises with the increasing in length of pollution layer and its position. It was noted that the experimental tests in laboratory for non-uniform contamination are in strong alignment with simulation studies. The results of this analysis should expand our understanding about the performance of outdoor insulators under specific contaminated conditions. The knowledge gathered can be used to enhance the configuration of insulators used in contaminated regions and it is believed that the current study has resulted methodology to estimate reliably and realistically the pollution performance of cylindrical porcelain insulators. [ABSTRACT FROM AUTHOR]

Published

2021

4. Measurement and evaluation of the flashover voltage on polluted cap and pin insulator: An experimental and theoretical study.

Author

Belhouchet, Khaled, Ghadbane, Ismail, Zemmit, Abderrahim, Ouchen, Lyamine, and Zorig, Assam

Subjects

*STRAY currents, *FINITE element method, *SURFACE potential, *STRESS concentration, *ANALYSIS of variance, *FLASHOVER

Abstract

• The study examines flashover voltage on cap and pin insulator in polluted environments using experiments and simulations. • Experiments replicate real-world pollution and measure flashover voltages on insulators. • ANOVA and FEM methods offer a comprehensive understanding of flashover phenomena on insulators. • FEM simulations model insulator behavior, detailing electrical field distribution and stress. • ANOVA and FEM provide insights into flashover voltage impacts, aiding robust insulation system development. This study investigates the flashover voltage on high voltage insulators in polluted environments, employing a combination of experimental and theoretical approaches. Utilizing Analysis of Variance (ANOVA) and the Finite Element Method (FEM), the research aims to offer a thorough comprehension of the phenomenon. The experimental aspect of the study involves subjecting insulators to polluted environments, replicating real-world scenarios, and measuring the resulting flashover voltages. This experimental study focuses on investigating flashover pollution, where artificial pollution is introduced into an experimental model. An observational approach is employed to assess the impact of conductivity and pollution distribution on the 1512 L cap and pin insulator, as well as its proposed experimental model. Complementing the experimental approach, the theoretical aspect of the study employs the FEM method to simulate and model the insulator's behaviour under pollution. This computational technique enables a detailed analysis of the electrical field distribution, surface potential, and stress repartition across the surface of the insulator. Simulations further explore the impact of pollution on flashover voltage and leakage current. The FEM results are then compared with experimental findings to validate the model's accuracy and reliability. By analyzing the collected data, the ANOVA technique is applied to identify significant differences in flashover voltage under diverse pollution levels. This statistical approach allows for the determination of the most influential factors affecting insulator performance. This research offers valuable insights into the influence of flashover voltage on high-voltage insulators in polluted environments, contributing to the development of more robust and efficient insulation systems. The combination of ANOVA and FEM methods provides a robust framework for understanding and predicting insulator performance, ultimately benefiting the power industry and promoting energy sustainability. [ABSTRACT FROM AUTHOR]

Published

2024

5. A novel application of artificial intelligence technology for outdoor high-voltage composite insulator.

Author

Belhouchet, Khaled, Zemmit, Abderrahim, Bayadi, Abdelhafid, Ouchen, Lyamine, and Zorig, Assam

Subjects

*COMPOSITE insulators, *ELECTRIC fields, *VOLTAGE, *CORONA discharge, *FINITE element method, *BIOLOGICALLY inspired computing

Abstract

• Modelling of three-dimensional model of a 220 kV composite insulator and its associated corona ring using COMSOL software. • Investigating the relationship between corona ring design variables and electric field strength. • Bat Algorithm is an innovative method to reduce electric field intensity in critical areas of composite insulators. • Combining Experimental Design Methodology and Bat algorithm can be a powerful tool for optimizing corona ring design. • Achieving a significant decrease in maximum electric field strength. The distribution of the electric field plays a crucial role in evaluating the effectiveness of composite insulators. This research presents an innovative approach for optimizing the design of corona rings, aiming to decrease the electric field intensity in critical areas to satisfactory levels. The investigation examined the correlation among corona ring design variables and the intensity of the electric field close to the energized-end fitting in a 220 kV composite insulator equipped with a corona ring. Using design of experiment methods, the impact of three corona ring design parameters – corona ring diameter (R), ring tube diameter (Dr), and corona ring height (H) – was assessed. A novel nonlinear mathematical objective function was formulated, connecting the electric field magnitude to the structural parameters of the corona ring. Subsequently, the Bat algorithm, a bio-inspired optimization technique, was employed to enhance the initial corona ring design and mitigate the electric field intensity. Finally, the Finite Element Method (FEM) was utilized to simulate and evaluate the voltage distribution and electric field stress. The optimization process resulted in a substantial decrease in the highest electric field magnitude, by 58.6 % compared to the insulator with the threshold value, and 75 % when devoid of a corona ring. Additionally, the research highlighted the significant influence of ring tube thickness on the distribution of the electric field. The combination of experimental design and the Bat algorithm proved to be a powerful tool for optimizing the design of corona rings on transmission line composite insulators, providing precise solutions for optimizing corona discharge problems and enhancing the reliability of power transmission systems. [ABSTRACT FROM AUTHOR]

Published

2024