M. Tayseer scite author profile

In this research, digital image processing method (DIPM) is used as an innovative approach to predict precisely the shape of electrical tree (ET) in cross-linked polyethylene (XLPE) power cables in the presence of air voids based on the field calculation using finite-element method (FEM). With the help of DIPM, two case studies are held to detect the accurate parameters of either the first initiated major branch or the tips of the major branches of ET. A hyperbolic needle-to-plane simulation model is proposed to illustrate the ET inception and propagation stages. The non-uniform electric fields thatare accompanied with the electrical treeing phenomenon are calculated using FEM as one of the most effective numerical methods to deal with non-uniform shapes. The predicted shapes of ET initiation and growth are provided in an innovative manner with the implemented hybrid connection between FEM and DIPM for the two proposed case studies. Direction branching approach and deviation angle branching approach are provided in this work to predict the shape and the direction of ET branched voids. The validity of the proposed model is assessed with the help of available previous experimental and simulation data.

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FPGA control system technology for integrating the PV/wave/FC hybrid system using ANN optimized by MFO techniques

Talaat

Alblawi

Tayseer

et al. 2022

Sustainable Cities and Society

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An economic study concerning the cost reduction of the covered transmission conductors based on different optimization techniques

Talaat

El-Shaarawy

Tayseer

et al. 2021

Results in Engineering

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Voltage Variations and Composite Solid Insulation Effects on Electrical Tree Propagation Based on Finite Element Method

Tayseer

El-Zein

Talaat

2020

The Egyptian International Journal of Engineering Sciences and

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This paper investigates the effect of the voltage variations and the change of solid insulation material on the initiation and propagation of Electrical Tree (ET) through solid dielectrics based on the application of Finite Element Method (FEM) approach using the environmental domain of [COMSOL Multiphysics ] program as an innovative way to be used in the complicated study of Electrical Treeing Phenomenon (ETP). This research provides an innovative solution to suppress the initiation point of ET and suppress its growth rates using a composite solid insulation material of Poly-Vinyl Chloride (PVC) and Cross-Linked Polyethylene (XLPE) regardless to the mechanical features of this composition. In this research, the study cases are conducted for High Voltage (HV) and Extra High Voltage (EHV) power system networks as the effect of ETP is to be observed clearly. The simulation model is used in this research to imitate the proposed hyperbolic needleplane system. Case studies are compared between each others to validate the results

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M. Tayseer

Efficiency of different optimisation approaches for optimal parameters of the CSM for investigating the onset field due to corona point

Digital image processing for physical basis analysis of electrical failure forecasting in XLPE power cables based on field simulation using finite‐element method

FPGA control system technology for integrating the PV/wave/FC hybrid system using ANN optimized by MFO techniques

An economic study concerning the cost reduction of the covered transmission conductors based on different optimization techniques

Voltage Variations and Composite Solid Insulation Effects on Electrical Tree Propagation Based on Finite Element Method

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