ANALYSIS OF THE ELECTROMAGNETIC ENVIRONMENT ENGENDERED INSIDE A BUILDING BY A LIGHTNING PROTECTION SYSTEM (LPS)

Karim Belhoul and Slimane Bouazabia

References

  1. [1] A. Orlandi, C. Mazzetti, Z. Flisowski, and M. Yarmarkin, Systematic approach for the analysis of the electromagnetic environment inside a building during lightning strike, IEEE Transactions on Electromagnetic Compatibility, 40(4), 1998, 521–535.
  2. [2] I.A. Metwally and F.H. Heidler, Improvement of the lightning shielding performance of overhead transmission lines by passive shield wires, IEEE Transactions on Electromagnetic Compatibility, 45(2), 2003, 378–392.
  3. [3] A. Sowa, Induced voltages in electronic systems within building which are struck by lightning, Proc. 18th Int. Conf. Lightning Protection, Munich, Germany, 1985, pp. 239–243.
  4. [4] Protection Against Lightning-Part I: General Principles, IEC 62305-1, Ed. I, May, 2003.
  5. [5] A. Orlandi and F. Schietroma, Attenuation by a lightning protection system of induced voltages due to direct strikes to a building, IEEE Transactions on Electromagnetic Compatibility, 38(1), 1996, 43–50.
  6. [6] S. Cristina and A. Orlandi, Calculation on the induced effects due to a lightning strokes, Proceedings of the Institution of Electrical Engineers – B, 139(4), 1992, 374–380.
  7. [7] A. Sowa, Surge current distribution in building during a direct lightning stroke, Proc. IEEE Int. Symp. Electromagn. Compat, USA, 1991, 248–252.
  8. [8] F.K. Chew, M.R.M. Esa, and H. Ahmad, Dispersion of standard and nonstandard lightning current to ground in a telecommunication building, Int. Power Eng. Conf., Singapore, 2007, 207–212.
  9. [9] J. Kato, H. Kawano, T. Tominaga, and S. Kuramoto, Investigation of lightning surge current induced in reinforced concrete buildings by direct strikes, Int. Symp. Lightning Prot. EMC, Tokyo, Japan, 2001.
  10. [10] F. Lei and Z. Peibai, The digital model of high building struck by lightning, High Voltage Apparatus, 36(6), 2000, 3–7.
  11. [11] F. Lei and Z. Peibai, Computation of the induced electric field in a high building, High Voltage Engineering, 27(1), 2001, 52–54.
  12. [12] Z. Xiaoqing, C. Shuiming, and W. Weihan, Lightning transient responses involving frequency-dependent characteristics in the building steel structure, Journal of Tsinghua University (Science Technology), 37(6), 1997, 103–107.
  13. [13] C.A.F. Sartori and A. Orlandi, Optimization of the LPS configuration for minimization of the radiated electromagnetic field, Proc. IEEE Int. Symp. Electromagn. Compat, Washington, USA, 2, 2000, 827–832.
  14. [14] C.A.F. Sartori, J.R. Cardoso, et al., Constrained decision planning applied to field profile optimization in LPS of structures directly struck by lightning, IEEE Transactions on Magnetics, 38, 2002, 757–760.
  15. [15] W. Qing, F. Zhengcai, et al., Influence of tightening current waveform on magnetic fields in a building struck by lightning, High Voltage Engineering, 27, 2001, 7–9.
  16. [16] H. Wei, H. Jianming, et al., The electromagnetic field in the building struck by lightning, Ship Electronic Engineering, 24, 2004, 270–272.
  17. [17] J. Yafei, Z. Ke, et al., Calculation of the maximum magnetic field inside the lightning protection system of a building, High Voltage Engineering, 35, 2009, 914–918.
  18. [18] I.A. Metwally, W.J. Zischank, and F.H. Heidler, Measurement of magnetic fields inside single- and double-layer reinforced concrete buildings during simulated lightning currents, IEEE Transactions on Electromagnetic Compatibility, 46, 2004, 208–221.
  19. [19] Y. Baba and V.A. Rakov, Voltages induced on an overhead wire by lightning strikes to a nearby tall grounded object, IEEE Transactions on Electromagnetic Compatibility, 48(1), 212–224, 2006.
  20. [20] H.M. Ren, B.H. Zhou, V.A. Rakov, L.H. Shi, C. Gao, and J.H. Yang, Analysis of lightning-induced voltages on overhead lines using a 2-D FDTD method and Agrawal coupling model, IEEE Transactions on Electromagnetic Compatibility, 50(3), 2008, 651–569.
  21. [21] M.A. Uman, D.K. McLain, and E.P. Kreider, The electromagnetic radiation from a finite antenna, American Journal of Physics, 43, 1975, 33–38.
  22. [22] M.J. Master and M.A. Uman, Transient electric and magnetic fields associated with establishing a finite electrostatic dipole, American Journal of Physics, 51, 1983, 118–126.
  23. [23] M. Rubinstein and M.A. Uman, Methods for calculating the electromagnetic fields from a known source distribution: Application to lightning, IEEE Transactions on Electromagnetic Compatibility, 31(2), 1989, 183–189.
  24. [24] M. Paolone, et al., Lightning electromagnetic field coupling to overhead lines: theory, numerical simulations, and experimental validation, IEEE Transactions on Electromagnetic Compatibility, 51(3), 2009, 532–547.
  25. [25] Y. Wang, et al., FDTD analysis of the three dimensional magnetic field distribution inside a building under direct lightning stroke, 7th Asia-Pacific Int. Conf. on Lightning, November 1–4, 2011, Chengdu, China.
  26. [26] J. Chen, B. Zhou, F. Zhao, and S. Qiu, Finite-difference time-domain analysis of the electromagnetic environment in a reinforced concrete structure when struck by lightning, IEEE Trans. on Electromagn. Compat., 52(4), 2010, 914–920.
  27. [27] F. Rachidi, Review of field-to-transmission line coupling models with particular reference to lightning-induced voltages, X Int. Symp. On Lightning Protection, November 9–13, 2009, Curutiba, Brazil.
  28. [28] O. Beirl and H. Steinbigler, Simplified and fast estimation of induced voltages caused by lightning currents, Proc. 6th Int. Symp. High-Voltage Eng., 1989, New Orleans, LA, August 28–September 1, 635–638.
  29. [29] A. Orlandi, G.B. Lo Piparo, and C. Mazzetti, Analytical expressions for current share by means of a lightning protection system model, European Transactions on Electrical Power Engineering (ETEP), 5(2), 1995, 1–8.
  30. [30] C.A. Nucci, C. Mazzetti, F. Rachidi, and M. Ianoz, On lightning return stroke models for LEMP calculations, Proc. 19th International Conference on Lightning Protection, 1988, Graz.
  31. [31] C.A. Nucci, Lightning-induced over voltages on overhead power lines. part 1, return-stroke current models with specified channel-base current for the evaluation of return-stroke electromagnetic field, Cigr´e Paper Prepared Within the Framework of Task Force 33.01.01 of the CIGRE Working Group 33.01,1994. Electra No161, August 1995.
  32. [32] F. Heidler, Analytische Blitzstorm-Funktion zur LEMP-Berechnung, Paper 1.9, Munich, Septembre 16–20, 1985, 63–66.

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