INVESTIGATION OF SURGE CURRENT DISTRIBUTION IN LIGHTNING PROTECTION SYSTEM AND ELECTRICAL INSTALLATION OF BUILDING
Vol 22 No 33 (2013), Articles
Vol 22 No 33 (2013)

INVESTIGATION OF SURGE CURRENT DISTRIBUTION IN LIGHTNING PROTECTION SYSTEM AND ELECTRICAL INSTALLATION OF BUILDING

Articles
https://doi.org/10.7862/re.2013.26
Published August 10, 2022
Stanisław WYDERKA
Rzeszow University of Technology, Department of Power Electronics and Power Engineering, al. Powst. Warszawy 12 , 35-959 Rzeszow
Grzegorz MASŁOWSKI
Rzeszow University of Technology, Department of Electrical and Computer Engineering Fundamentals W. Pola 2, 35-959 Rzeszow
Robert ZIEMBA
Rzeszow University of Technology, Department of Electrical and Computer Engineering Fundamentals, W. Pola 2, 35-959 Rzeszów
Grzegorz KARNAS
Rzeszow University of Technology, Department of Electrical and Computer Engineering Fundamentals, W. Pola 2, 35-959 Rzeszów
Kamil FILIK
Rzeszow University of Technology, Department of Electrical and Computer Engineering Fundamentals, W. Pola 2, 35-959 Rzeszów
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Keywords

lightning protection system
electrical installation
surge current distribution
measurements and simulations
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Abstract

The paper presents results of the lightning protection system (LPS) tests for a small residential structure with the connected home appliances and electronics, conducted in 2013 at the new test site in Poland using the mobile surge current generator. Current surges were injected from generator to the air termination on the building roof. Current distribution in individual elements of test object was measured and registered with multi-channel electro-optical measurement system. The current waveshapes in the vertical ground electrodes differed from the injected current waveshapes and from the current waveshapes in other parts of the test system. Computer simulation using ATP-EMTP were carried out in order to verify the results of measurements. Vertical and horizontal ground electrodes were modeled for specified parameter resulting from the geometrical configuration of the system and the measured soil conductivity. Conducted investigations showed the significant influence of configuration, dimensions and impedance of test object on current distribution. A significant influence of frequency dependent components of the system impedances on current waveshapes has been noticed. Computed results show a good agreement with the experimental data. Small differences in the current waveshapes result mainly from the adopted double-exponential mathematical approximation which does not perfectly match the current injected from the generator.

https://doi.org/10.7862/re.2013.26
PDF (Język Polski)

References

[1] Masłowski G.: Analiza i modelowanie wyładowań atmosferycznych na potrzeby ochrony przed przepięciami. Uczelniane Wydawnictwa Naukowo-Dydaktyczne AGH, seria: Rozprawy, Monografie, nr 208, Kraków, 2010
[2] Rakov V.A., Uman M.A., Fernandez M.I., Mata C.T., Rambo K.J., Stapleton M.V., and Sutil R.R., Direct Lightning Strikes to the Lightning Protection System of a Residential Building: Triggered-Lightning Experiments, IEEE Trans. on Pow. Del., 17 (2002), n.2, pp. 575–586
[3] DeCarlo B. A., Rakov V. A., Jerauld J. E., Schnetzer G. H., Schoene J., Uman M. A., Rambo K. J., Kodali V., Jordan D. M., Maxwell G., Humeniuk S., Morgan M., Distribution of Currents in the Lightning Protective System of a Residential Building - Part I: Triggered-Lightning Experiments, IEEE Transactions on Power Delivery, vol. 23, n. 4, Oct. 2008 pp. 2439-2446
[4] Maslowski G., Rakov V.A., Wyderka S., Bajorek J., DeCarlo B.A., Jerauld J., Schnetzer G.H., Schoene J., Uman M.A., Rambo K.J., Jordan D.M. and Krata W., Testing of Lightning Protective System of a Residential Structure: Comparison of Data Obtained in Rocket-Triggered Lightning and Current Surge Generator Experiments, High Voltage Engineering, China, 34 (2008), n. 12, pp. 2575-2582
[5] Maslowski G., Wyderka S., Rakov V.A., DeCarlo B.A., Li L., Bajorek J., Ziemba R., Measurements and numerical modeling of currents in lightning protective system of a residential building. X International Symposium on Lightning Protection, Curitiba, Brazil, November 9-13, 2009, pp. 587-592.
[6] Maslowski G., Wyderka S., Rakov V.A., DeCarlo B.A., Li L., Bajorek J., Ziemba R., Experimenta investigation and numerical modeling of surge currents in lightning protective system of a residential building, Journal of Lightning Research, No.4, 2012, pp. 18-26
[7] Masłowski G., Wyderka S., Bajorek J., Ziemba R., Badanie efektywności urządzenia piorunochronnego niewielkiego obiektu budowlanego. Przegląd Elektrotechniczny, R. 86 nr 5/2010, ss. 229–232
[8] Masłowski G., Wyderka S. Układ probierczo-pomiarowy do poligonowych badań narażeń piorunowych, Przegląd Elektrotechniczny (Electrical Review), R. 88, NR 5a, 2012, ss. 67-72
[9] Buczek Ł., Wyderka S., Jaworski M., Światłowodowy system szerokopasmowej rejestracji sygnałów elektrycznych w środowisku wysokich napięć i silnych zaburzeń elektromagnetycznych, Przegląd Elektrotechniczny (Electrical Review), R. 88, NR 9a, 2012, ss. 171-174
[10] Wyderka S., Masłowski G., Ziemba R., Karnas G., Frequency Characteristics of Supplying Transformer and Electrical Appliances of Residential Building In Modeling of Lightning Current Distribution, ICLP, Vienna, Austria, September 2-7, 2012.
[11] Sunde, E. D., Earth Conduction Effects in the Transmission Systems, New York: Dover, 1968.
[12] Juan A. Martinez Velasco (Ed.), Power System Transients. Parameter Determination, CRC Press, Boca Raton, London, New York, October 2009
[13] Bajorek J., Knott M., Wyderka S.: Efficiency of ZnO arrester models simulation of lightning overvoltages. 21st ICLP, BERLIN, Germany 1992, Pap. No. 5.07.