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Magnetic pollution produced by underground XLPE 220 kV power cable in power plant

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Języki publikacji
EN
Abstrakty
EN
The expansion of the electrical network necessitates the construction of new power plants and the extension of overhead and underground power transmission and distribution systems. However, underground power cables, such as XPLE 220 kV, can cause significant electromagnetic pollution, particularly in urban areas. This paper focuses on the evaluation and prediction of such magnetic emissions using analytical, numerical simulation (the finite element analysis), and experimental measurement. The paper aim is to minimize the magnetic emissions through the adjustment of the horizontal and vertical distances (x, y) of cables, serving as a technical solution. Additionally, the study investigated the impact of faults with varying magnitude and frequency, considering different loads and conditions. The simulation results indicate that several factors contribute to the escalation of magnetic pollution. These factors include a close proximity between cables, faults, and high current intensities.... However, as the distance between cables increases both horizontally and vertically, the strength of the magnetic field decreases, leading to a reduction in magnetic pollution. A comparison was carried out to assess the magnetic emissions of the underground cable, revealing a notable resemblance between the measured and calculated values. Ultimately, the validated simulation model serves as a valuable tool for evaluating, predicting, and mitigating electromagnetic pollution under different fault conditions and positions.
Słowa kluczowe
Czasopismo
Rocznik
Strony
art. no. 2024104
Opis fizyczny
Bibliogr. 23 poz., rys., tab.
Twórcy
  • Department of Electrical Engineering Laboratoire de Genie Electrique, Kasdi Merbah University, Ghardaia Road, P.O. Box 511, Ouargla 30000, Algeria
  • Department of Electrical Engineering Laboratoire de Genie Electrique, Kasdi Merbah University, Ghardaia Road, P.O. Box 511, Ouargla 30000, Algeria
autor
  • Department of automatic, APELEC laboratory Djilali Liabes University, Sidi Bel Abbes 22000 Algeria
autor
  • Department of Electrical Engineering Djillali Liabes University, Sidi Bel Abbes 22000 Algeria
  • Department of Electrical Engineering Laboratoire de Genie Electrique, Kasdi Merbah University, Ghardaia Road, P.O. Box 511, Ouargla 30000, Algeria
Bibliografia
  • 1. Krika W, Ahmed Nour El Islam A, Benyekhlef L, Benhamida F. Electromagnetic simulation of subsea power cable pollution. International Black Sea Coastline Countries Scientific Research Symposium VI Giresun, Turkey, 2021.
  • 2. Ahmed Nour El Islam A, Krika W, Houari B, Benhamida F, Horch A. Simulation of the Electromagnetic Field in the Vicinity of the Overhead Power Transmission Line. European Journal of Electrical Engineering 2019; 21: 49-53. https://doi.org/10.18280/ejee.210108.
  • 3. Krika W, Ayad ANE, Benyekhlef L, Benhamida F. Thermal effect of harmonic and short circuit in underground electric cable. International Black Sea Coastline Countries Scientific Research Symposium VI, Giresun, Turkey, 2021.
  • 4. Boudjella H, Ayad ANEI, Rouibah T, Larouci B, Alghamdi TAH, Althobaiti A, i in. Magnetic field evaluation around 400 KV underground power cable under harmonics effects. Diagnostyka 2022; 23(2): 1-10. https://doi.org/10.29354/diag/150068.
  • 5. Kurniawan A, Puspasari V, Arwati G, Khaerudini D. Investigation of AC interference on underground gas pipeline due to parallel overhead high voltage power line. 2022; 2652 s. 050017. https://doi.org/10.1063/5.0106271.
  • 6. Krika W, Ayad ANEI, Aayad A. Magnetic field simulation of three-core submarine power cable. Acta Technica Napocensis - Series: Applied Mathematics, Mechanics, and ENGINEERING 2022; 65(2).
  • 7. Said A, Hashima S, Fouda MM, Saad MH. Deep Learning-Based Fault Classification and Location for Underground Power Cable of Nuclear Facilities. IEEE Access 2022; 10: 70126-42. https://doi.org/10.1109/ACCESS.2022.3187026.
  • 8. Ghoneim SSM, Ahmed M, Sabiha NA. Transient Thermal Performance of Power Cable Ascertained Using Finite Element Analysis. Processes 2021; 9(3): 438. https://doi.org/10.3390/pr9030438.
  • 9. del-Pino-López JC, Cruz-Romero P, Bravo-Rodríguez JC. Evaluation of the power frequency magnetic field generated by three-core armored cables through 3D finite element simulations. Electric Power Systems Research 2022; 213: 108701. https://doi.org/10.1016/j.epsr.2022.108701.
  • 10. del-Pino-López JC, Cruz-Romero P. Experimental validation of ultra-shortened 3D finite element electromagnetic modeling of three-core armored cables at power frequency. Electric Power Systems Research 2022; 203: 107665. https://doi.org/10.1016/j.epsr.2021.107665.
  • 11. Zhu K, Han W, Lee WK, Pong PWT. On-Site NonInvasive Current Monitoring of Multi-Core Underground Power Cables With a Magnetic-Field Sensing Platform at a Substation. IEEE Sensors Journal 2017; 17(6): 1837-1848. https://doi.org/10.1109/JSEN.2017.2651886.
  • 12. Dein AZE, Gouda OE, Lehtonen M, Darwish MMF. Mitigation of the Electric and Magnetic Fields of 500-kV Overhead Transmission Lines. IEEE Access 2022; 10: 33900-33908. https://doi.org/10.1109/ACCESS.2022.3161932.
  • 13. El Dein A, Gouda O, Ghoneim S, Zaini H. Mitigation of Magnetic Flux Density of Underground Power Cable and its Conductor Temperature Based on FEM. IEEE Access 2021; 1-1. https://doi.org/10.1109/ACCESS.2021.3121175.
  • 14. Technical Catalogue and Datasheet. Underground XLPE 220 Kv Power Cable. ABB High Voltage Cables User's Guide.
  • 15. Technical Catalogue. Maintenance Instruction and Installation Help of Underground Cable 220 kV XLPE. Electric Gas Power Plant of Sonelgaz Society at Hassi Messaoud, Ouargla, West of Algeria, The Real Geometrical Configuration.
  • 16. Theory for the Magnetic Fields 2012. No Currents Interface User's Guide, Magnetostatic Equation AC/DC Module. Multiphysics Software COMSOL 4.3 2012. www.comsol.com/support/releasenotes/4.2/acdc.
  • 17. Meunier G. The Finite Element Method: Theory, Implementation, and Applications. 395th edition, hardcover, Wiley 2013.
  • 18. Karl Lonngren E, Sava Savov V, Randy Jost J. Fundamentals of Electromagnetics with MATLAB (Electromagnetic Waves). 1st and 2nd Edition, Scitech Publishing; 2nd edition (October 31, 2007).
  • 19. Tabatabaei NM, Bizon N. Numerical Methods for Energy Applications, Springer (electronic), Power Systems, ISBN 978-3-030-62191-9. https://doi.org/10.1007/978-3-030-62191-9.
  • 20. Govind B, Misra DK, Khanna SP, Kumar A, Bano S. Errors in Measurement of Magnetic Field and Magnetic Moment with its Associated Uncertainty. Lecture Notes in Electrical Engineering 2023; 906. https://doi.org/10.1007/978-981-19-2468-2.
  • 21. Mathur P, Raman S. Electromagnetic Interference (EMI): Measurement and Reduction Techniques. Journal of Electronic Materials 2020; 49(5): 2975–98. https://doi.org/10.1007/s11664-020-07979-1.
  • 22. George G, Karady E, Holbert K. Electrical Energy Conversion and Transport: An Interactive ComputerBased Approach. Chapter 5, Second Edition, John Wiley & Sons, Inc., Hoboken, New Jersey, ISBN 978- 0-470-93699-3, 2013.
  • 23. Rabah D, Djillali M. Calculation and analysis of inductive coupling effects for HV transmission lines on aerial pipelines. 2014; 90: 151-156. https://doi.org/10.12915/pe.2014.09.39.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-59121890-d78e-4fe9-9853-c1a719624b99
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