MERENJE BUKE USLED KORONE U OKOLINI NADZEMNOG VODA

Fleksibilnost elektroenergetskog sistema / Zbornik CIGRE (2023).  (str 575- 592)

AUTOR(I) / AUTHOR(S): Iva Salom, Milenko Kabović, Vladimir Čelebić, Marko Ralić, Jovanka Gajica, Dejan Todorović, Nebojša Petrović, Nada Curović, Valerijan Aksić

E-ADRESA / E-MAIL: iva.salom@pupin.rs

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DOI:  10.46793/CIGRE36.0575S

SAŽETAK / ABSTRACT:

Buka koja potiče od visokonaponskih nadzemnih vodova je jedan od problema sa kojim se sreću operateri prenosne mreže širom sveta. Ovaj problem je postao vrlo aktuelan i ispituje se na globalnom nivou kroz teorijska istraživanja same fizičke pojave korone, razvoj empirijskih formula za proračun, matematičko modelovanje i sotverske simulacije. Poseban deo istraživanja odnosi se na merenje buke u okolini nadzemnog voda, čiji rezultati predstavljaju najrelevantnije podatke koji se uključuju u korekcije empirijskih formula i matematičkih modela. U ovom radu prikazana je usvojena metodologija merenja, zasnovana na više relevantnih standarda, kao i podataka iz opsežne literature (istraživanja, naučni radovi, izveštaji). Metodologija uključuje izbor vremenskog intervala, mernog mesta, merne opreme, položaja mikrofona,  poništavanje rezidualnog zvuka. Posebno su prikazani obrađeni rezultati jednog merenja.

KLJUČNE REČI / KEYWORDS:

korona, merenje buke, nivo zvuka, nadzemni vod

LITERATURA / REFERENCES:

  • EPRI AC Transmission Line Reference Book—200 kV and Above, EPRI, Paolo Alto California, 3rd ed., Final report, December 2005
  • F. Kiessling, P. Nefzger, J.F. Nolasco, U. Kaintzyk, “Overhead Power Lines – Planning, Design, Construction,” Springer-Verlag Berlin Heidelberg 2003
  • P.S. Maruvada, “Corona Performance of High Voltage Transmission Lines,” Taylor & Francis Group, London, UK, 2000
  • ESKOM Holdings Ltd, T. Pillay, S. Bisnath “The Planning, Design and Construction of Overhead Power Lines, 132 kV & above,” Crown Publications cc, Johannesburg, February 2005
  • CIGRÉ Technical Brochure 278 „ The Influence of Line Configuration on Environment Impacts of Electrical Origin – Principles of Overhead Line Design,” CIGRE Working Group B2.06, 2005
  • CIGRÉ Green Book, CIGRÉ, International Council on Large Electric Systems (CIGRE), Paris, France, SC B2 Overhead lines, Konstantin O. Papailiou Editor, Springer International Publishing Switzerland 2017
  • T. Wszolek, “Diagnostic Symptoms of Corona Audible Noise in Continuous Monitoring Systems,” Technical Note, Archives of Acoustics, No. 36, Vol. 1, pp 151-160, 2011
  • U. Straumann, “Mechanism of the tonal emission from ac high voltage overhead transmission lines,” Journal of Physics D Applied Physics 44125(44), February 2011
  • X. Bian, L. Chen, D. Yu, J.M.K. Alpine, L. Wang, Z. Guan, F. Chen, W. Yao, S. Zhao, “Influence of Aged Conductor Surface Conditions on AC Corona-generated Audible Noise with a Corona Cage,” IEEE Transactions on Dielectrics and Electrical Insulation Vol. 19, No. 6; pp. 2017-2043, December 2012
  • Q. Li, “Acoustic Noise Emitted from Overhead Line Conductors,” PhD Thesis, The University of Manchester, School of Electrical and Electronic Engineering, 2013
  • I. Gavranov, Lj. Dimitrov, Z. Milojević, “Corona EHV AC Transmission Lines as Noise Source in the Environment,” 18th International Symposium on Electrical Apparatus and Technologies (SIELA), Bourgas, Bulgaria, May 2014
  • F.A.M. Rizk, G.N. Trinh, “High Voltage Engineering,” Taylor & Francis Group, 6000 Broken Sound Parkway NW, Suite 300 Boca Raton, FL 33487-2742, 2014
  • P. Sames, M. Goossens, “Messtechnische Felduntersuchungen zu Koronageräuschen,” Umwelt und Geologie, Lärmschutz in Hessen, Heft 5, 2015
  • U. Schichler, R. Woschitz, A. Pirker, K. Reich, M. Leonhardsberger, O. Oberzaucher, “Audible Noise Performance of OHL Conductor Bundles,” First South East European Regional CIGRÉ Conference, Slovenia, Portorož 7-8 June 2016, SEERC 2016
  • EirGrid Evidence Based Environmental Studies Study 8: Noise, Literature review and evidence based field study on the noise effects of high voltage transmission development, May 2016
  • B. Wan, W. He, C. Pei, X. Wu, Y. Chen, J. Zhang, L. Lan, “Audible noise performance of conductor bundles based on cage test results and comparison with long term data,” Energies 2017, Vol. 10, No. 958, 2017
  • E.A. Piana, A. Donini, R. Spezie, R. Turri, R. Cortina, “Prediction of the audible noise generated by corona discharge on a power transmission line: A model validation. In Proceedings of the 24th International Congress on Sound and Vibration (ICSV), London, UK, 23–27 July 2017; International Institute of Acoustics and Vibrations: Auburn, AL, USA, 2017
  • N. Petrović, „Uticaj prečnika provodnika, broja provodnika po fazi, razmaka u snopu i međufaznog rastojanja 400 kV nadzemnih vodova na naponski gradijent provodnika i jačinu buke usled korone,“ STK B2 Nadzemni vodovi, R B2 03, 33 Savetovanje CIGRE Srbija, Zlatibor, 5 – 8. jun 2017
  • A. Čaršimamović, „Modeliranje napona početka stacionarne korone zasnovano na mjerenjima električnog polja,“ doktorska disertacija, Elektrotehnički fakultet, Univerzitet u Sarajevu, 2018
  • W. He, B. Wan, Y. Liu, X. Liu, S. Huang, Y. Zhang, J. Zhang, “Audible noise spectral characteristics of high-voltage AC bundled conductors at high altitude,” IET Gener Transm Distrib. 2021; 15:1304–1313, 2021
  • E. Stracqualursi, R. Araneo, S. Celozzi. “The Corona Phenomenon in Overhead Lines: Critical Overview of Most Common and Reliable Available Models,” Energies 2021, 14. 6612, pp. 1-33, October 2021
  • SRPS ISO 1996-1 Akustika – Opisivanje, merenje i ocenjivanje buke u životnoj sredini – Deo 1: Osnovne veličine i procedure, novembar 2019. (identičan sa EN ISO 1996-1:2016)
  • SRPS ISO 1996-2 Akustika – Opisivanje, merenje i ocenjivanje buke u životnoj sredini – Deo 2: Određivanje nivoa zvučnog pritiska, novembar 2019. (identičan sa EN ISO 1996-2:2017)
  • IEEE Standard for the Measurement of Audible Noise from Overhead Transmission Lines, IEEE Power and Energy Society, IEEE Std 656-2018 (Revision of IEEE Std 656-1992)
  • P. Sames, M. Goossens: „Messtechnische Felduntersuchungen zu Koronageräuschen“, Hessisches Landesamt für Umwelt und Geologie, Wiesbaden, 2015
  • J. Engelen et al.: „Ermittlung und Beurteilung von Koronageräuschen an Höchstspannungsfreileileitungen“, Lärmbekämpfung Bd. 6 Nr. 4, 2012
  • A. Siegemund: „Schalltechnisches Gutachten auf Basis der TA Lärm“, Errichtung einer 380‐kV‐Freileitung Weida ‐ Remptendorf, 2021
  • SRPS ISO 3744:2011 Akustika — Određivanje nivoa zvučne snage i nivoa zvučne energije izvora buke na osnovu zvučnog pritiska — Inženjerska metoda za približno slobodno polje iznad refleksione
    ravni (identičan sa EN ISO 3744:2010)
  • SRPS ISO 3746:2011 Akustika — Određivanje nivoa zvučne snage i nivoa zvučne energije izvora buke na osnovu zvučnog pritiska — Informativna metoda korišćenjem merne površine koja obuhvata
    izvor iznad refleksione ravni (identičan sa EN ISO 3746:2010)
  • SRPS EN 61672-1:2015 Elektroakustika – Merači nivoa zvuka – Deo 1: Specifikacije (identičan sa EN 61672-1:2013; ANSI/ASA S1.4-2014/Part 1 / IEC 61672-1:2013)
  • Pravilik o merilima nivoa zvuka, Službeni glasnik RS, br. 39/2014
  • https://www.bksv.com/media/doc/bp2025.pdf
  • https://svantek.com/products/sv200a-4g-integrated-noise-monitoring-station/
  • https://svantek.com/products/sv-307a-noise-monitoring-station/
  • https://svantek.com/products/svan-979-class-1-sound-vibration-level-meter/
  • https://www.pce-instruments.com/english/api/getartfile?_fnr=1562497&_dsp=inline